JP4285397B2 - Optical pickup unit control method and optical disk apparatus - Google Patents

Description

  The present invention relates to a method of controlling an optical pickup unit that performs at least one of recording and reproduction of information on an optical disc, and an optical disc apparatus.

  Some peripheral devices used by connecting to an electronic device such as a personal computer can receive power from the connected electronic device such as a personal computer. For example, since a universal serial bus (hereinafter referred to as “USB”) has a power supply bus, there is a connected device that is supplied with power by this power supply bus.

  Here, a conventional optical disc apparatus capable of supplying power via USB will be described as an example with reference to the drawings. FIG. 5 is a block diagram showing a configuration of a conventional optical disc apparatus. In FIG. 5, 1 is an optical disk, 2 is a feed motor, 3 is a spindle motor, 4 is an optical pickup unit, 5 is an LD driver, 6 is a feed motor driver, 7 is a spindle motor driver, 8 is an actuator driver, and 9 is a read amplifier. 10 is a CD encoder, 11 is a CD-ROM encoder, 12 is a buffer memory, 13 is an ATIP detector, 14 is a CD-ROM decoder, 15 is a CD servo processor, 16 is a system bus, 17 is a CPU, and 18 is a read-only memory. (ROM), 19 is a main memory, 20 is a non-volatile memory, 21 is an interface unit, 22 is an interface bus, 23 is a power supply unit, 24 is a PC power supply, 25 is an AC adapter, and 26 is a DIPSW.

  The optical disk 1 is rotated by the spindle motor 3, and the optical pickup unit 4 is moved in the radial direction of the optical disk 1 by the feed motor 2, and data is written to and read from the optical disk 1. The spindle motor 3 is driven by a spindle motor driver 7, and the feed motor 2 is driven by a feed motor driver 6. The optical pickup unit 4 is driven by an actuator driver 8.

  The feed motor driver 6, spindle motor driver 7, and actuator driver 8 are servo controlled by a CD servo processor 15. The optical pickup unit 4 includes a laser diode, which is driven by an LD driver 5 and controlled by a CD encoder 10. The CD-ROM encoder 11 acquires data to be recorded from the buffer memory 12 in which it is stored, performs an encoding process for recording, and inputs the result to the CD encoder 10.

  In the reproduction system, the optical signal obtained from the optical disk 1 and the optical pickup unit 4 is processed by the read amplifier 9 and used as a feedback signal to the CD servo processor 15 and becomes an input signal to the ATIP detector 13, and its output signal is Feedback is provided to the CD encoder 10. The CD-ROM decoder 14 demodulates the CD signal, performs data demodulation using the output signal of the CD servo processor 15, and stores the result in the buffer memory 12. The buffer memory 12 is a memory for temporarily storing recording data and demodulated data. These data are exchanged with the host computer via the interface unit 21 by communication using the interface bus 22.

  The CPU 17 performs logical judgment and calculation. Reference numeral 18 denotes a read only memory (ROM) having a program storage area for storing a control program and a recording control program for the optical disk recording apparatus. A main memory 19 is used as a storage area necessary for recording control and reproduction control.

  The system bus 16 is a data transfer bus in the optical disc apparatus 101. The power supply portion stably supplies a voltage from the power supply unit 23 to each control chip. The power supply unit 23 receives power supply from the AC adapter 25 and the PC power supply 24. The PC power supply 24 has a mechanism for supplying a voltage to the power supply unit 23 of the drive in conjunction with the voltage of the power supply terminal VBUS from the interface unit 21 connected to the personal computer by USB, and automatically in conjunction with the ON / OFF of the USB power supply. Start and stop the drive.

  Here, the control of the optical pickup unit in the conventional optical disc apparatus will be described with reference to FIG. FIG. 6 is a flowchart showing control of a conventional optical pickup unit. When the optical disk 1 is inserted, the optical disk apparatus rotates the spindle motor 3 to start the starting process, applies focus servo and tracking servo, and determines the type of the optical disk 1 (S1). A tracking signal and a focus error signal from the optical disc 1 are detected by the optical pickup unit 4 on which the optical pickup is mounted (S2), and the detected tracking error signal and focus error signal are amplified by the read amplifier 9 (S3). . The focus error signal refers to a shift in the focal direction between the light beam spot emitted from an objective lens (not shown) provided in the optical pickup and the recording surface of the optical disc 1, and the tracking error signal refers to the light beam. This is a deviation in the radial direction of the optical disc between the spot and the information track of the optical disc 1. The amplified tracking error signal and focus error signal are sent to the CD servo processor 15, where a tracking drive signal and a focus drive signal are generated (S4). The generated tracking drive signal and focus drive signal are sent from the CD servo processor 15 to the actuator driver 8 to control the optical pickup unit 4 (S5). The optical pickup unit 4 reads and writes data on the optical disc 1 (S6).

As a prior example in this field, there is (Patent Document 1) and the like.
JP-A-11-39671

  An optical disk device connected to an electronic device such as a computer as described above may naturally operate using a limited current supplied from the connected electronic device. However, the current consumption of the optical disk device is not always constant. For example, in the case of an external type optical disk device connected via USB or the like, the operation of the optical pickup unit 4 based on the focus error signal and the tracking error signal It also varies depending on the current consumption of the actuator driver 8 that performs control. When the current consumption fluctuates and the current supply from the PC power supply 24 supplied via the USB exceeds the allowable current amount, for example, even if it is instantaneous, it is connected to a commercial power outlet or the like It is necessary to receive a current supply from the AC adapter 25.

  However, in the above conventional configuration, an external power source such as the AC adapter 25 is required, and a power supply source such as an outlet must be nearby, so that the user's convenience cannot be maximized.

  The present invention has been made to solve the above-described problems, and can operate without exceeding the allowable range of the current supply source even when the allowable current amount has no tolerance due to instantaneous current consumption. An object of the present invention is to provide a control method for an optical pickup unit.

The present invention has been made to solve the above-described problems, and receives light reflected from an optical disc, generates a focus error signal based on the reflected light, and performs focus control based on the focus error signal. When the pickup unit and the optical disc apparatus receive a current supply from the computer , the focus error signal voltage is compared with a predetermined threshold value when the optical pickup unit performs focus control, and the focus error signal voltage is set to the predetermined threshold value. Control means for replacing the voltage of the focus error signal with the same voltage as the predetermined threshold when the threshold is exceeded , and storage means for storing a plurality of predetermined threshold values selected according to the operating state of the optical pickup unit. And a plurality of predetermined thresholds corresponding to at least the startup time of the optical pickup unit There is a threshold corresponding to the time of accessing the optical disc of the optical pickup unit, threshold value corresponding to the time of access to the optical disk of the optical pick-up unit is an optical disk apparatus characterized by greater than a threshold corresponding to the startup of the optical pickup unit.

In addition, the present invention receives the reflected light from the optical disc, generates a tracking error signal based on the reflected light, and the optical pickup unit that is tracking-controlled based on the tracking error signal, and the optical disc apparatus receive a current supply from the computer. When tracking control of the optical pickup unit is performed, the voltage of the tracking error signal is compared with a predetermined threshold, and when the voltage of the tracking error signal exceeds the predetermined threshold, the voltage of the tracking error signal is And a storage means for storing a plurality of predetermined threshold values selected in accordance with the operating state of the optical pickup unit . The plurality of predetermined threshold values include at least the optical pickup. Threshold value corresponding to unit startup and light of optical pickup unit There is a threshold corresponding to when accessing the disk, the threshold value corresponding to the time of access to the optical disk of the optical pick-up unit is an optical disk apparatus characterized by greater than a threshold corresponding to the startup of the optical pickup unit.

According to the present invention, when the optical disc apparatus is supplied with a current from the computer, the control means compares the voltage of the focus error signal with a predetermined threshold value when the control means performs focus control of the optical pickup unit. When the voltage exceeds the predetermined threshold, the focus error signal voltage is controlled so as not to exceed a predetermined amount by replacing the voltage of the focus error signal with the same voltage as the predetermined threshold. Since the focus drive signal that is generated based on the focus error signal voltage and drives the objective lens to focus does not require a current that exceeds the allowable range of the current supply source, the current consumption of the optical disk device is usually the current supply. Even if the allowable range of the source is momentarily exceeded, the power consumption of the optical disk device It can be added to limit the now, can not exceed the allowable range of the current supply source. As a result, it becomes possible to limit the current consumption of the optical disk device and not to exceed the allowable range of the current supply source, so there is no tolerance in the allowable current amount of the current supply source due to instantaneous current consumption. Even in this case, it is possible to realize an optical disc apparatus that can operate without exceeding the allowable range of the current supply source. In addition, a plurality of predetermined threshold values selected according to the operation status of the optical pickup unit are stored, and the predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and an optical pickup unit accessing the optical disc. There is a corresponding threshold value, and the threshold value when the optical pickup unit accesses the optical disc is larger than the threshold value corresponding to the startup time of the optical pickup unit. It is possible to optimally cope with an access to an optical disk with little change.

In addition, according to the present invention, when the optical disk apparatus is supplied with a current from the computer, the control means compares the tracking error signal voltage with a predetermined threshold when the control means performs tracking control of the optical pickup unit, and performs tracking. When the error signal voltage exceeds a predetermined threshold, the tracking error signal voltage is replaced with the same voltage as the predetermined threshold so that the tracking error signal voltage does not exceed a predetermined amount in any case. However, since the tracking drive signal generated based on the tracking error signal voltage for driving the focus of the objective lens does not require a current that exceeds the allowable range of the current supply source, the current consumption of the optical disc apparatus is usually reduced. Even if the allowable range of the current source is momentarily exceeded, It is possible to restrict the consumption current of the disk device, can not exceed the allowable range of the current supply source. As a result, it becomes possible to limit the current consumption of the optical disk device and not to exceed the allowable range of the current supply source, so there is no tolerance in the allowable current amount of the current supply source due to instantaneous current consumption. Even in this case, it is possible to realize an optical disc apparatus that can operate without exceeding the allowable range of the current supply source. In addition, a plurality of predetermined threshold values selected according to the operation status of the optical pickup unit are stored, and the predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and an optical pickup unit accessing the optical disc. There is a corresponding threshold value, and the threshold value when the optical pickup unit accesses the optical disc is larger than the threshold value corresponding to the startup time of the optical pickup unit. It is possible to optimally cope with an access to an optical disk with little change.

According to the first aspect of the present invention, an optical pickup unit that receives reflected light from an optical disc, generates a focus error signal based on the reflected light, and performs focus control based on the focus error signal, and an optical disc apparatus supplies current from a computer. When the focus control of the optical pickup unit is performed, the voltage of the focus error signal is compared with a predetermined threshold, and when the voltage of the focus error signal exceeds the predetermined threshold, the voltage of the focus error signal And a storage means for storing a plurality of predetermined threshold values selected according to the operating state of the optical pickup unit, and the plurality of predetermined threshold values include at least Threshold value for optical pickup unit activation and optical disc of optical pickup unit There a threshold value corresponding to the time of access of the threshold corresponding to the time of access to the optical disk of the optical pick-up unit is characterized in that greater than a threshold corresponding to the startup of the optical pickup unit. When the control means performs focus control of the optical pickup unit, the voltage of the focus error signal is compared with a predetermined threshold, and when the voltage of the focus error signal exceeds the predetermined threshold, the voltage of the focus error signal is The focus error signal voltage is controlled so as not to exceed a predetermined amount in any case by substituting it with the same voltage as the threshold value, and generated based on the focus error signal voltage to drive the objective lens in focus. Since the focus drive signal does not require a current that exceeds the allowable range of the current supply source, even if the current consumption of the optical disk device momentarily exceeds the allowable range of the current supply source, the consumption of the optical disk device It is possible to limit the current and not to exceed the allowable range of the current source Kill. As a result, it becomes possible to limit the current consumption of the optical disk device and not to exceed the allowable range of the current supply source, so there is no tolerance in the allowable current amount of the current supply source due to instantaneous current consumption. Even in this case, it is possible to realize an optical disc apparatus that can operate without exceeding the allowable range of the current supply source. In addition, a plurality of predetermined threshold values selected according to the operation status of the optical pickup unit are stored, and the predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and an optical pickup unit accessing the optical disc. There is a corresponding threshold value, and the threshold value when the optical pickup unit accesses the optical disc is larger than the threshold value corresponding to the startup time of the optical pickup unit. It is possible to optimally cope with an access to an optical disk with little change.

According to a second aspect of the present invention, an optical pickup unit that receives reflected light from an optical disc, generates a tracking error signal based on the reflected light, and is tracking-controlled based on the tracking error signal, and an optical disc apparatus supplies current from a computer. When the tracking control of the optical pickup unit is performed, the tracking error signal voltage is compared with a predetermined threshold value, and the tracking error signal voltage is exceeded when the tracking error signal voltage exceeds the predetermined threshold value. control means for replacing the voltage to the same voltage and the predetermined threshold, the predetermined threshold being selected in accordance with the operation state of the optical pickup unit comprises a memory means for storing a plurality, and the plurality of predetermined threshold At least the optical pick-up unit with the corresponding threshold when starting the optical pick-up unit There is a threshold corresponding to when accessing the Ppuyunitto optical disk, the threshold value corresponding to the time of access to the optical disk of the optical pick-up unit is characterized in that greater than a threshold corresponding to the startup of the optical pickup unit. When the control means performs focus control of the optical pickup unit, the voltage of the focus error signal is compared with a predetermined threshold, and when the voltage of the focus error signal exceeds the predetermined threshold, the voltage of the focus error signal is The tracking error signal voltage is controlled so as not to exceed a predetermined amount in any case by substituting it with the same voltage as the threshold value, and generated based on the tracking error signal voltage to drive the objective lens for tracking. Since the tracking drive signal does not require a current that exceeds the allowable range of the current supply source, even if the current consumption of the optical disk device momentarily exceeds the allowable range of the current supply source, the current consumption of the optical disk device Can be limited so that the current source tolerance is not exceeded. . As a result, it becomes possible to limit the current consumption of the optical disk device, so that the allowable range of the current supply source is not exceeded, so that the allowable current of the current supply source is not marginal due to instantaneous current consumption Even so, it is possible to realize an optical disc apparatus that can operate without exceeding the allowable range of the current supply source. In addition, a plurality of predetermined threshold values selected according to the operation status of the optical pickup unit are stored, and the predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and an optical pickup unit accessing the optical disc. There is a corresponding threshold value, and the threshold value when the optical pickup unit accesses the optical disc is larger than the threshold value corresponding to the startup time of the optical pickup unit. It is possible to optimally cope with an access to an optical disk with little change.

According to a third aspect of the present invention, the storage means stores a plurality of predetermined threshold values selected according to the type of the optical disk to be used, and the plurality of predetermined threshold values correspond to at least a threshold corresponding to a DVD and a CD There is a threshold value, and the threshold value corresponding to the DVD is larger than the threshold value corresponding to the CD . As a result , the focus tracking variable range that is different depending on the type of optical disk to be used is optimally supported, so that it is possible to efficiently limit the current consumption of the optical disk apparatus and not to exceed the allowable range of the current supply source. can do.

Fourth aspect of the present invention, receives the reflected light from the optical disc, generates a focus error signal based on the reflected light, a method of controlling an optical pickup unit which is focus control on the basis of the focus error signal, the optical disc apparatus When the current is supplied from the computer, when performing focus control of the optical pickup unit, the voltage of the focus error signal is compared with a predetermined threshold, and when the voltage of the focus error signal exceeds the predetermined threshold, Replaces the voltage of the focus error signal with the same voltage as the predetermined threshold, stores a plurality of predetermined thresholds selected according to the operation state of the optical pickup unit, and at least activates the optical pickup unit in the plurality of predetermined thresholds The threshold corresponding to the time and the optical pickup unit There a threshold value is intended threshold value corresponding to the time of accessing the optical disc of the optical pickup unit is equal to or greater than a threshold corresponding to the startup of the optical pickup unit. When focus control of the optical pickup unit is performed, the voltage of the focus error signal is compared with a predetermined threshold value. When the voltage of the focus error signal exceeds the predetermined threshold value, the voltage of the focus error signal is the same as the predetermined threshold value. In any case, the focus error signal voltage is controlled so as not to exceed a predetermined amount, and a focus drive signal is generated based on the focus error signal voltage to drive the objective lens. Since there is no request for a current that exceeds the allowable range of the current supply source, even if the current consumption of the optical disk apparatus usually exceeds the allowable range of the current supply source instantaneously, the current consumption of the optical disk apparatus Limits can be added and current supply tolerances can not be exceeded As a result, it becomes possible to limit the current consumption of the optical disk device, so that the allowable range of the current supply source is not exceeded, so that the allowable current of the current supply source is not marginal due to instantaneous current consumption Even so, it is possible to realize a method of controlling the optical pickup unit that can operate without exceeding the allowable range of the current supply source. In addition, a plurality of predetermined threshold values selected according to the operation status of the optical pickup unit are stored, and the predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and an optical pickup unit accessing the optical disc. There is a corresponding threshold value, and the threshold value when the optical pickup unit accesses the optical disc is larger than the threshold value corresponding to the startup time of the optical pickup unit. It is possible to optimally cope with an access to an optical disk with little change.
The invention according to claim 5 is a method of controlling an optical pickup unit that receives reflected light from an optical disk, generates a tracking error signal based on the reflected light, and is tracking-controlled based on the tracking error signal, and an optical disk device When the current is being supplied from the computer , the tracking error signal voltage is compared with a predetermined threshold when performing the tracking control of the optical pickup unit, and when the tracking error signal voltage exceeds the predetermined threshold, Replaces the voltage of the tracking error signal with the same voltage as the predetermined threshold, stores a plurality of predetermined thresholds selected according to the operation state of the optical pickup unit, and at least activates the optical pickup unit in the plurality of predetermined thresholds Sometimes corresponding threshold and optical pickup unit to optical disc There is a threshold corresponding to the time of access, in which threshold values corresponding to the time of accessing the optical disc of the optical pickup unit is equal to or greater than a threshold corresponding to the startup of the optical pickup unit. When tracking control of the optical pickup unit is performed, the voltage of the tracking error signal is compared with a predetermined threshold. If the voltage of the tracking error signal exceeds the predetermined threshold, the voltage of the tracking error signal is the same as the predetermined threshold. In any case, the tracking error signal voltage is controlled so as not to exceed a predetermined amount, and a tracking drive signal for tracking the objective lens is generated based on the tracking error signal voltage. Since there is no request for a current that exceeds the allowable range of the current supply source, even if the current consumption of the optical disk apparatus usually exceeds the allowable range of the current supply source instantaneously, the current consumption of the optical disk apparatus It is possible to add a limit so that the allowable range of the current source is not exceeded. Rukoto can. As a result, it becomes possible to limit the current consumption of the optical disk device, so that the allowable range of the current supply source is not exceeded, so that the allowable current of the current supply source is not marginal due to instantaneous current consumption Even so, it is possible to realize a method of controlling the optical pickup unit that can operate without exceeding the allowable range of the current supply source. In addition, a plurality of predetermined threshold values selected according to the operation status of the optical pickup unit are stored, and the predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and an optical pickup unit accessing the optical disc. There is a corresponding threshold value, and the threshold value when the optical pickup unit accesses the optical disc is larger than the threshold value corresponding to the startup time of the optical pickup unit. It is possible to optimally cope with an access to an optical disk with little change.

(Embodiment 1)
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is an external view of an optical disc apparatus according to an embodiment of the present invention. In FIG. 1, 101 is an optical disk device, 102 is an upper lid, 103 is a USB connector, 104 is a USB cable, 105 is a computer, 106 is an AC adapter, 107 is an outlet, and 108 is a DC jack.

  The optical disc apparatus 101 is a so-called external type that is not built in an electronic device such as a computer, and an optical disc is loaded by opening the upper lid 102. Reference numeral 103 denotes a USB connection connector. When the USB cable 104 is connected to the computer 105, for example, the computer 105 can read data from the optical disk or write data to the optical disk. Reference numeral 106 denotes an AC adapter that steps down and rectifies the voltage from the outlet 107 of a commercial power supply (100 V or the like), and supplies current to the optical disc apparatus 101 from the DC jack 108.

  Usually, the current acquisition of the external type optical disc apparatus 101 may depend on the AC adapter 106 as well as on the power bus such as the USB cable 104. Whether the current required by the optical disk apparatus 101 can be always supplied by the power supply bus of the USB cable 104 mainly depends on the current supply capability of the computer 105 and the current consumption of the optical disk apparatus 101. Optical disks include CD-ROM, CD-R / RW, DVD-ROM, DVD-RAM, DVD-R / RW, and DVD + R / RW, and the optical disk device 101 can support one or several types of these optical disks 1. Things are included.

  If the power supply circuit has a current voltage suitable for use inside the optical disc apparatus 101, the AC power supply 106 is not used, and the commercial power supply is directly pulled in with an appropriate wire and connector. There may be. Further, a commercial power source may not be used, and a battery built in or externally attached to the optical disc apparatus 101 may be used as a driving power source. When the optical disk device 101 is used, it is preferable to drive only the power supply bus of the USB cable 104 in consideration of the convenience of the user and save the trouble of connecting several cables.

  The USB cable 104 normally has one connection terminal on the side of the electronic device such as the computer 105 and the side of the optical disc apparatus 101, but there may be a plurality of terminals on the side of the electronic device such as the computer 105 in some cases. By doing so, the allowable range of the current supplied from the electronic device via the USB cable 104 or the like can be improved.

  In the present embodiment, since the optical disc apparatus 101 is controlled so that it can be driven only by the power supply bus of the USB cable 104, the AC adapter 106 is used from the outlet 107 of a commercial power supply (100V or the like) in the standard use state. There is no need to step down and rectify the voltage and supply current from the DC jack 108 to the optical disc apparatus 101. When it is necessary to increase the recording speed beyond the standard use state, the AC adapter 106 may be connected to the outlet 107 to receive a current supply. For example, the standard use state is the low current consumption mode, and when the standard use state is exceeded, the high-speed operation mode is used. The low current consumption mode includes 4 × speed for CD writing, 12 × speed for CD reading, 2 × speed for DVD writing, 4 × speed for DVD reading, and the like. Further, the high-speed operation mode includes 24 × speed for writing CD, 24 × speed for reading CD, 8 × speed for writing DVD, 8 × speed for reading DVD, and the like.

  FIG. 2 is a block diagram showing the configuration of the optical disk recording apparatus according to one embodiment of the present invention. In FIG. 2, 1 is an optical disk, 2 is a feed motor, 3 is a spindle motor, 4 is an optical pickup unit, 5 is an LD driver, 6 is a feed motor driver, 7 is a spindle motor driver, 8 is an actuator driver, and 9 is a read amplifier. 10 is a CD encoder, 11 is a CD-ROM encoder, 12 is a buffer memory, 13 is an ATIP detector, 14 is a CD-ROM decoder, 15 is a CD servo processor, 16 is a system bus, 17 is a CPU, and 18 is a read-only memory. (ROM), 19 is a main memory, 20 is a non-volatile memory, 21 is an interface unit, 22 is an interface bus, 23 is a power supply unit, 24 is a PC power supply, 25 is an AC adapter, and 26 is a DIPSW.

  The optical disk 1 is rotated by the spindle motor 3, and the optical pickup unit 4 is moved in the radial direction of the optical disk 1 by the feed motor 2, and data is written to and read from the optical disk 1. The spindle motor 3 is driven by a spindle motor driver 7, and the feed motor 2 is driven by a feed motor driver 6. The optical pickup unit 4 is driven by an actuator driver 8.

  The feed motor driver 6, spindle motor driver 7, and actuator driver 8 are servo controlled by a CD servo processor 15. The optical pickup unit 4 includes a laser diode, which is driven by an LD driver 5 and controlled by a CD encoder 10. The CD-ROM encoder 11 acquires data to be recorded from the buffer memory 12 in which it is stored, performs an encoding process for recording, and inputs the result to the CD encoder 10.

  In the reproduction system, the optical signal obtained from the optical disk 1 and the optical pickup unit 4 is processed by the read amplifier 9 and used as a feedback signal to the CD servo processor 15 and becomes an input signal to the ATIP detector 13, and its output signal is Feedback is provided to the CD encoder 10. The CD-ROM decoder 14 demodulates the CD signal, performs data demodulation using the output signal of the CD servo processor 15, and stores the result in the buffer memory 12. The buffer memory 12 is a memory for temporarily storing recording data and demodulated data. These data are exchanged with the host computer via the interface unit 21 by communication using the interface bus 22.

  The CPU 17 performs logical judgment and calculation. Reference numeral 18 denotes a read only memory (ROM) having a program storage area for storing a control program and a recording control program for the optical disk recording apparatus. A main memory 19 is used as a storage area necessary for recording control and reproduction control.

  Here, the CPU 17 is a control unit according to the present invention, and includes a CD encoder 10, a CD-ROM encoder 11, a buffer memory 12, a CD-ROM decoder 14, a CD servo processor 15, a ROM 18, a main memory 19, a nonvolatile memory 20, and an interface unit. Signals sent from each part of 21 are input, arithmetic processing of these signals is performed, the result (signal) of this arithmetic processing is sent to each part, each part is driven and processed, and each part is controlled Is.

  The system bus 16 is a data transfer bus in the optical disc apparatus 101. The power supply portion stably supplies a voltage from the power supply unit 23 to each control chip. The power supply unit 23 receives power supply from the AC adapter 25 and the PC power supply 24. The PC power supply 24 has a mechanism for supplying a voltage to the power supply unit 23 of the drive in conjunction with the voltage of the power supply terminal VBUS from the interface unit 21 connected to the personal computer by USB, and automatically in conjunction with the ON / OFF of the USB power supply. Start and stop the drive.

  In the present embodiment, in the standard use state, the optical disc apparatus 101 is controlled so that it can be driven only by the power supply bus of the USB cable 104, so that current supply via the AC adapter 25 is not necessary. Here, the standard use state is a low current consumption mode or the like. Therefore, it is possible to save the trouble of connecting several cables when using the optical disc apparatus 101, and the usability of the user is improved.

  Next, control of the optical pickup unit of the optical disc apparatus according to the embodiment of the present invention will be described with reference to FIG.

  FIG. 3 is a flowchart showing control of the optical pickup unit of the optical disc apparatus according to the embodiment of the present invention. When the optical disk 1 is inserted, the optical disk apparatus 101 rotates the spindle motor 3 to start the activation process, applies focus servo and tracking servo, and determines the type of the optical disk (S1). The tracking signal and focus error signal from the optical disk 1 are detected by the optical pickup unit 4 on which the optical pickup is mounted (S2), and the detected tracking error signal and focus error signal are amplified by the read amplifier 9 (S3). . The focus error signal refers to a shift in the focal direction between the light beam spot emitted from an objective lens (not shown) provided in the optical pickup and the recording surface of the optical disc 1, and the tracking error signal refers to the light beam. This is a deviation in the radial direction of the optical disc between the spot and the information track of the optical disc 1. The amplified tracking error signal and focus error signal are sent to the CD servo processor 15, where voltage measurement of the tracking error signal and focus error signal is first performed (S11). The measured voltage value is sent to the CPU 17, where it is compared with a predetermined voltage threshold value to determine the current supply operation mode (S12). If the current supply is not in the USB bus mode (AC adapter mode), the CD servo processor 15 generates a tracking error signal and a focus drive signal (S4). The generated tracking drive signal and focus drive signal are sent from the CD servo processor 15 to the actuator driver 8 to control the optical pickup unit 4 (S5). The optical pickup unit 4 reads and writes data on the optical disc 1 (S6).

  When the current supply is in the USB bus mode, the CPU 17 reads the clip value corresponding to the type of the disk from the clip values that are thresholds of a predetermined voltage stored in the ROM 18, and the CD servo processor 15. (S13). The CD servo processor 15 compares the voltage value of the measured tracking error signal and the focus error signal with the clip value which is a predetermined voltage threshold value, and determines the tracking error signal voltage based on the comparison result. At least one of the focus error signal voltages is changed (S14). The changed tracking error signal and focus error signal are sent to the CD servo processor 15 to generate a tracking error signal and a focus drive signal (S4). The generated tracking drive signal and focus drive signal are sent from the CD servo processor 15 to the actuator driver 8 to control the optical pickup unit 4 (S5). The optical pickup unit 4 reads and writes data on the optical disc 1 (S6).

  In this embodiment, a voltage corresponding to the upper limit of the allowable range of the current supply source is set with respect to a predetermined voltage threshold, and the tracking error signal voltage value and the focus error signal voltage value are determined in advance. When the voltage threshold is exceeded, the voltage is the same as the predetermined voltage threshold. By doing so, the consumption current of the optical disc apparatus 101 does not exceed the upper limit of the allowable range of the current supply source.

  In the present embodiment, the predetermined voltage threshold value is variable according to the type of the optical disc 1 used and the operating state of the optical pickup unit 4. By doing so, it becomes possible to optimally cope with different tracking and focus tracking variable ranges depending on the type of the optical disk 1 used, and in the operating state of the optical pickup unit 4, there is a change in current consumption at the peak. It is possible to optimally cope with an access to the optical disc 1 in which the change in current consumption during a large start-up and a peak is small. For example, when the type of the optical disk 1 is different, a predetermined threshold voltage is set larger for the DVD than for the CD, and when the operation state of the optical pickup unit 4 is different, the peak current consumption A threshold value of a predetermined voltage is set to be larger when accessing an optical disc with a small change in current consumption at the peak time than when the change is large.

  Next, the change of the tracking error signal and the focus error signal when current supply is not possible in the USB bus mode in the embodiment of the present invention will be described with reference to the drawings.

  FIG. 4 is a diagram showing the tracking error signal and the focus error signal after the change according to the embodiment of the present invention. FIG. 7 is a diagram illustrating a conventional tracking error signal and focus error signal. 4A and 7A show the tracking error signal voltage, the tracking drive signal voltage, and the tracking drive signal current from the top, and FIGS. 4B and 7B show the top. FIG. 5 shows a focus error signal voltage, a focus drive signal voltage, and a focus drive signal current. 4 and 7, 51 and 61 are tracking error signal voltages, 52 and 62 are tracking drive signal voltages, 53 and 63 are focus error signal voltages, 54 and 64 are focus drive signal voltages, and 72 and 82 are tracking drive signal voltages. Currents 74 and 84 are focus drive signal currents. Tracking error signal voltage 51, tracking drive signal voltage 52, tracking drive signal voltage 72, focus error signal voltage 53, focus drive signal voltage 54, focus drive signal current 74, tracking error signal voltage 61, tracking drive signal voltage 62, and tracking drive The signal current 82, the focus error signal voltage 63, the focus drive signal voltage 64, and the focus drive signal voltage 84 respectively correspond to the tracking error signal voltage, tracking drive signal voltage, tracking drive signal current, focus error signal voltage, and focus drive signal voltage. And the focus drive signal current.

  The tracking error signal voltage 61 and the focus error signal voltage 63 shown in FIG. 7 are measured by the CD servo processor 15. The measured voltage value is sent to the CPU 17, where the operation mode of current supply is determined. At this time, when the current supply is in the USB bus mode, the tracking error signal voltage 61 and the focus error signal voltage 63 shown in FIGS. 7A and 7B are set as predetermined voltage thresholds. Based on the clipped value, the waveform peak portion is clipped like the tracking error signal voltage 51 and the focus error signal voltage 53 shown in FIGS. 4 (a) and 4 (b). Here, clipping means that a voltage exceeding a predetermined voltage threshold is regarded as the same value as a set clip value which is a predetermined voltage threshold, and is processed. That is, when a predetermined voltage threshold is exceeded, the voltage is the same as the predetermined voltage threshold. Here, the same voltage means a voltage within about 90% with respect to a predetermined threshold value of the voltage including the accuracy of changing the voltage value of the tracking error signal and the focus error signal.

  Since the waveform peak portions of the tracking error signal voltage 51 and the focus error signal voltage 53 are limited by the clip value corresponding to the type of the inserted optical disc 1, the tracking drive signal and focus drive generated based on them are limited. The signal also changes like the tracking drive signal voltage 52 and the focus drive signal voltage 54. Further, the tracking drive current 82 and the focus drive current 84 shown in FIG. The tracking drive current 72 and the focus drive current 74 shown in FIG. Therefore, the tracking drive current 72 and the focus drive current 74 can be sufficiently kept within the allowable range of the current supply source.

  As a result, even when the current consumption of the optical disk device 101 normally exceeds the allowable range of the current supply source instantaneously, it becomes possible to limit the current consumption of the optical disk device 101, and the allowable range of the current supply source Can not be exceeded.

  This realizes a control method for an optical pickup that can operate without exceeding the allowable range of the current supply source even when the allowable current amount of the current supply source has no tolerance due to instantaneous current consumption. be able to.

  In addition, by using the optical pickup control method described above for an optical disc apparatus, even if there is no tolerance in the allowable current amount of the current supply source due to instantaneous current consumption, the allowable range of the current supply source is exceeded. Thus, the operable optical disk device 101 can be realized.

  Further, when the optical disk apparatus 101 having connection means having both the power transmission function and the signal transmission function is used, the current supply by the AC adapter 25 or the like is not required in the standard use state. This eliminates the trouble of connecting several cables and improves the usability of the user.

  Further, when the connection means having both the power transmission function and the signal transmission function is a USB, and the electronic device connected by the connection means is a computer, the optical disc apparatus 101 uses the USB as a power source, and a standardized current. Therefore, it becomes easy to know the upper limit of the allowable range of the current supply source.

  In this embodiment, a voltage corresponding to the upper limit of the allowable range of the current supply source is set as a predetermined voltage threshold, and the tracking error signal voltage value and the focus error signal voltage value are determined in advance. When the voltage threshold is exceeded, the voltage is the same as the predetermined voltage threshold. However, the predetermined voltage threshold is less than the upper limit of the allowable range of the current supply source. A value of 80% or 70% may be set. When a predetermined voltage threshold is exceeded, a value of 80% or 70% is set with respect to the predetermined voltage threshold. May be.

  In the present embodiment, the predetermined voltage threshold is variable according to the type of optical disk used and the operation state of the optical pickup. However, the predetermined voltage threshold is used. It is not limited to one that can be changed according to the type of optical disk to be used and the operating state of the optical pickup. Optimum support for different tracking and focus tracking variable ranges depending on the type of optical disk used, and in the operating state of the optical pickup, there is a large change in current consumption at peak time and a change in current consumption at peak time. In consideration of the optimum response even when accessing a small optical disk, it is preferable that the predetermined voltage threshold varies according to the type of optical disk used and the operating state of the optical pickup.

  The present invention realizes a control method for an optical pickup that can operate without exceeding the allowable range of the current supply source even when the allowable current amount of the current supply source is not marginal due to instantaneous current consumption. The present invention is applicable to a method for controlling an optical pickup unit that performs at least one of recording and reproduction of information on an optical disc, an optical disc apparatus, and the like.

1 is an external view of an optical disc apparatus according to an embodiment of the present invention. 1 is a block diagram showing a configuration of an optical disc recording apparatus according to an embodiment of the present invention. 6 is a flowchart showing control of the optical pickup unit of the optical disc apparatus according to the embodiment of the present invention. The figure which shows the tracking error signal and focus error signal after a change in one embodiment of this invention Block diagram showing the configuration of a conventional optical disc apparatus Flow chart showing control of conventional optical pickup unit Diagram showing conventional tracking error signal and focus error signal

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optical disk 2 Feed motor 3 Spindle motor 4 Optical pick-up unit 5 LD driver 6 Feed motor driver 7 Spindle motor driver 8 Actuator driver 9 Read amplifier 10 CD encoder 11 CD-ROM encoder 12 Buffer memory 13 ATIP detector 14 CD-ROM decoder 15 CD Servo processor 16 System bus 17 CPU
18 Read-only memory (ROM)
19 Main Memory 20 Nonvolatile Memory 21 Interface Unit 22 Interface Bus 23 Power Supply Unit 24 PC Power Supply 25 AC Adapter 26 DIPSW
51 Tracking error signal voltage 52 Tracking drive signal voltage 53 Focus error signal voltage 54 Focus drive signal voltage 61 Tracking error signal voltage 62 Tracking drive signal voltage 63 Focus error signal voltage 64 Focus drive signal voltage 72 Tracking drive current 74 Focus drive current 82 Tracking Drive current 84 Focus drive current 101 Optical disc device 102 Upper lid 103 USB connector 104 USB cable 105 Computer 106 AC adapter 107 Outlet 108 DC jack

Claims (5)

An optical pickup unit that receives reflected light from the optical disc, generates a focus error signal based on the reflected light, and is focus-controlled based on the focus error signal;
When the optical disc apparatus is supplied with a current from a computer , the focus error signal voltage is compared with a predetermined threshold value when the optical pickup unit performs focus control, and the focus error signal voltage exceeds the predetermined threshold value. Control means for replacing the voltage of the focus error signal with the same voltage as the predetermined threshold when exceeding,
Storage means for storing a plurality of predetermined threshold values selected according to the operation state of the optical pickup unit ,
The plurality of predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and a threshold value corresponding to the time when the optical pickup unit accesses the optical disc,
An optical disc apparatus characterized in that a threshold value corresponding to access of the optical pickup unit to the optical disc is larger than a threshold value corresponding to activation of the optical pickup unit . An optical pickup unit that receives reflected light from the optical disc, generates a tracking error signal based on the reflected light, and is tracking-controlled based on the tracking error signal;
When the optical disk device is supplied with a current from a computer , the tracking error signal voltage is compared with a predetermined threshold value when the optical pickup unit performs tracking control, and the tracking error signal voltage exceeds the predetermined threshold value. Control means for replacing the voltage of the tracking error signal with the same voltage as the predetermined threshold when exceeding,
Storage means for storing a plurality of predetermined threshold values selected according to the operation state of the optical pickup unit ,
The plurality of predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and a threshold value corresponding to the time when the optical pickup unit accesses the optical disc,
An optical disc apparatus characterized in that a threshold value corresponding to access of the optical pickup unit to the optical disc is larger than a threshold value corresponding to activation of the optical pickup unit . The storage means stores a plurality of predetermined threshold values selected according to the type of optical disk to be used,
The plurality of predetermined threshold values include at least a threshold value corresponding to DVD and a threshold value corresponding to CD,
The optical disk apparatus according to claim 1, wherein a threshold value corresponding to the DVD is larger than a threshold value corresponding to the CD . A method for controlling an optical pickup unit that receives reflected light from an optical disc, generates a focus error signal based on the reflected light, and is focus-controlled based on the focus error signal,
When the optical disc apparatus is supplied with a current from a computer , the focus error signal voltage is compared with a predetermined threshold value when the optical pickup unit performs focus control, and the focus error signal voltage exceeds the predetermined threshold value. If exceeded , replace the voltage of the focus error signal with the same voltage as the predetermined threshold ,
Storing a plurality of predetermined threshold values selected according to the operating state of the optical pickup unit;
The plurality of predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and a threshold value corresponding to the time when the optical pickup unit accesses the optical disc,
The method of controlling an optical pickup unit, wherein a threshold value corresponding to access of the optical pickup unit to the optical disc is larger than a threshold value corresponding to the time of activation of the optical pickup unit. A method of controlling an optical pickup unit that receives reflected light from an optical disc, generates a tracking error signal based on the reflected light, and is tracking-controlled based on the tracking error signal,
When the optical disk device is supplied with a current from a computer , the tracking error signal voltage is compared with a predetermined threshold value when the optical pickup unit performs tracking control, and the tracking error signal voltage exceeds the predetermined threshold value. If exceeded, replace the voltage of the tracking error signal with the same voltage as the predetermined threshold ,
Storing a plurality of predetermined threshold values selected according to the operating state of the optical pickup unit;
The plurality of predetermined threshold values include at least a threshold value corresponding to the time when the optical pickup unit is activated and a threshold value corresponding to the time when the optical pickup unit accesses the optical disc,
The method of controlling an optical pickup unit, wherein a threshold value corresponding to access of the optical pickup unit to the optical disc is larger than a threshold value corresponding to the time of activation of the optical pickup unit.

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