KR20120092808A - Driving method in optical disc apparatus - Google Patents

Abstract

PURPOSE: A method for driving an optical disk in an optical disk device is provided to stably drive an optical disk drive when power is supplied through a USB(Universal Serial Bus) without external power. CONSTITUTION: The strength of a driving signal of a spindle motor(11) is controlled by referring to a driving signal of a sled motor(12). The sled motor transfers an optical pickup to an inner circumference. The spindle motor rotates an optical disk. When the absolute value of the driving signal of the sled motor is larger than 1, the driving signal of the spindle motor is controlled with a second value. When a laser beam emitted from the optical pickup is moved to an external circumference along with a spiral track formed on the optical disk, the first value is larger than a driving signal applied to the sled motor.

Description

Driving method in optical disc apparatus {Driving method in optical disc apparatus}

The present invention relates to a driving method in an optical disk device.

Optical discs such as CDs (Compact Discs), DVDs (Digital Versatile Discs), and BDs (Blu-ray Discs) are portable, removable, and record and store large amounts of data. Recordable optical disc drives are widely used as peripherals for desktop or notebook computers.

Recently, as desktop computers have been slimmer and notebook computers have become thinner, external optical disk drives, not internal optical disk drives, have become popular, in which case one external optical disk drive can be used in multiple computers. There is an advantage that can be divided into use.

External optical disk drives can be connected to a host computer via a universal serial bus (USB) interface to send and receive data, and can also be powered via USB from the host without an external power source.

When an external optical disk drive is powered by USB without an external power source, two or more motors may operate while increasing the speed or performing a search operation, thereby causing an unstable operation due to insufficient power supply.

Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to provide a method for driving an optical disk drive with a low current.

Another object of the present invention is to provide a method which makes it possible to drive a motor with a low current without software consideration.

The driving method in the optical disk apparatus according to an embodiment of the present invention for achieving the above object, the drive signal of the rotary motor for rotating the optical disk with reference to the drive signal of the feed motor for moving the optical pickup in and out It is characterized by limiting the size.

In one embodiment, when the absolute value of the drive signal of the transfer motor is greater than the first value, the drive signal of the rotary motor may be limited to the second value.

In one embodiment, the first value may be set greater than a drive signal applied to the transfer motor when the laser beam emitted from the optical pickup is moved outward along a spiral track formed in the optical disk.

In one embodiment, the second value is in consideration of one or more of the magnitude of the power applied to the optical disk device, the maximum driving voltage applied to the transfer motor, the driving voltage required to rotate the optical disk at a predetermined rotational speed. Can be set.

An optical disk apparatus according to another embodiment of the present invention, the transfer motor for moving the optical pickup in and out around; A rotating motor for rotating the optical disk; And comparing the absolute value of the drive signal of the transfer motor with a first value, comparing the drive signal of the rotary motor with a second value, and comparing the drive signal of the rotary motor with the second based on the comparison result. And a logic circuit for limiting to two values.

In one embodiment, the optical disk device further comprises an interface for connecting with a host, and the logic circuit can be operated only when power is supplied through the interface.

Therefore, even when power is supplied via USB without an external power source, the optical disk drive can be stably driven.

1 shows the current consumption when the sled motor and the spindle motor are driven at the same time,
2 illustrates that the driving of the spindle motor is limited according to an embodiment of the present invention.
Figure 3 illustrates a logic circuit for limiting the drive of the spindle motor in accordance with one embodiment of the present invention,
Figure 4 shows an embodiment of the configuration of a disk device to which the present invention is applied.

Hereinafter, an embodiment of a driving method in an optical disk apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

If the maximum current consumption is limited, such as an external optical disc drive (ODD), it is important to ensure that the drive current does not exceed a certain amount. The operation that consumes a lot of current in the ODD can be referred to as a motor drive. Among them, a sled motor, which is a transfer motor for moving the optical pickup in and out, and a spindle motor, which rotates the optical disk, consume a lot of current.

In the case of a sled motor, in general, a certain amount of current is consumed only when a movement occurs, and in the absence of a movement, almost no current is consumed. Spindle motors consume almost constant current when rotating at a constant speed and more current when accelerating or decelerating.

1 shows the current consumption when the sled motor and the spindle motor are driven simultaneously. Sled motors and spindle motors always draw current under voltage. In particular, the spindle motor consumes a large amount of current while consuming a high voltage when accelerating to increase the number of revolutions. At this acceleration point, if the sled motor moves, the current consumption, which is the sum of the currents consumed by the two motors, becomes very high. If the current supplied to the ODD is limited to THcurrent, the ODD may become inoperable due to lack of current supply as soon as the current is consumed higher than THcurrent.

In the conventional case, the two motors were driven with a time difference in software so as to avoid driving the sled motor and the spindle motor which consume a lot of current for low current operation.

The present invention restricts the drive of the spindle motor while the sled motor is being driven so that a large amount of current does not flow at the same time. That is, when the sled motor moves, the drive voltage of the acceleration / deceleration of the spindle motor is limited to a predetermined value or less.

The increase in the drive current of the spindle motor, that is, the rotary motor, mainly occurs only in the CLV (Constant Linear Velocity) mode or in the case of acceleration (Spin Up) .In this case, even if the driving voltage of the rotary motor is limited, the acceleration and deceleration time is long and there is no problem in operation. none. In addition, since the drive of the sled motor is completed in a very short time, it does not significantly affect the acceleration / deceleration operation of the spindle motor. Even if the spindle motor momentarily lowers the driving voltage during acceleration, there is no problem with the rotation and the acceleration period is only slightly longer.

2 illustrates that the driving of the spindle motor is limited according to an embodiment of the present invention.

In Fig. 2, when the driving voltage of the sled motor is larger than THsled + or smaller than Thsled-, the maximum value of the driving voltage of the spindle motor is limited to THspd. With proper setting of THspd, the total current consumption can be reduced below THcurrent as the spindle motor drive voltage is lowered even if the sled motor is driven while the rotary motor is accelerating. Therefore, it does not matter if the current supplied to the ODD is limited below THcurrent.

3 illustrates a logic circuit for limiting driving of a spindle motor according to an embodiment of the present invention, and may include a comparator and an analog switch.

If the drive voltage of the sled motor is larger than THsled + or smaller than THsled-, i.e., when the optical pickup is moved more than a predetermined track in the circumferential or inner circumferential direction according to the track jump or track skip, S1 becomes one. If the drive voltage of the spindle motor is greater than THspd, i.e. in an acceleration situation in which the rotational speed of the disk must be increased, S2 becomes one. If both S1 and S2 are 1, the drive signal of the spindle motor is output by THspd by the analog switch. That is, when S1 is 1, the drive signal of the spindle motor is clamped to THspd or less. When S1 is 1, the drive signal of the spindle motor cannot exceed THspd, so the overall current consumption is reduced.

In the normal recording or reproducing operation, when following a spirally formed track while moving the laser beam focused on the disc through the objective lens of the optical pickup, the actuator supporting the objective lens is driven to move the objective lens to the outer periphery, After the objective lens moves a lot in the circumferential direction from the center of the optical pickup, the sled motor is driven to move the entire optical pickup outward.

As a condition for clamping the drive voltage of the spindle motor, the drive voltage of the sled motor is compared with THsled + and THsled-. The size of THsled + is used to move the laser beam gradually along the spiral track using the actuator and the sled motor. When the optical pickup can be set to be larger than the voltage applied to the sled motor to move a few tracks outward.

In addition, THspd, the limit value of the drive voltage of the spindle motor, takes into account at least one of the magnitude of the power applied to the ODD, the maximum drive voltage applied to the sled motor, and the drive voltage required to rotate the disk at a predetermined rotational speed. Can be determined.

The driving method according to the present invention can be applied to various types of disc devices capable of playing or recording CDs, DVDs, and BD discs. FIG. 4 shows an embodiment of a configuration of a disc device to which the present invention is applied. It is.

The disk apparatus according to the present invention includes a spindle motor 11, a sled motor 12, an optical pickup 20 for recording data to or reading data from an optical disk using a laser beam, the spindle A recording / reproducing unit for driving the motor 11, the sled motor 12, and the optical pickup 20 and processing servo signals and recording / reproducing data, a control unit 70 and a host for controlling the recording / reproducing system; It may be configured to include an interface unit 80 connected to send and receive data or to receive a command, the recording / reproducing unit optical driver 30, digital signal processing unit 40, R / F unit 50, servo / It may be configured to include a drive unit 60 and the like. The optical driver 30 may be included in the optical pickup 20.

The logic circuit for limiting the driving signal of the spindle motor of FIG. 3 may be included in the servo / drive unit 60 and implemented.

The digital signal processor 40 adds an error correction code (ECC) or the like to the digital data to be converted into a recording format, and the optical driver 30 outputs a light quantity driving signal according to the input signal, and the optical pickup 20 records data on the optical disc 10 or reads data from the recording surface of the optical disc 10 in accordance with the light amount driving signal.

The R / F unit 50 filters the signal detected by the optical pickup 20 to output a binary signal by shaping the filter, and also generates and outputs a tracking error signal TE, a focus error signal FE, and an RF signal. In addition, the digital signal processor 40 restores the binary signal to original data using its own clock synchronized with the binary signal, and the servo / drive unit 60 receives the signal from the R / F unit 50. To generate a servo signal for focusing servo, tracking servo, sled servo, and spindle servo, and to drive the spindle motor 11 for rotating the optical disk 10, and the inner and outer circumferential directions of the optical pickup 20. Drive the sled motor 12 to move to the target, and also drive the current required for the focusing servo and tracking servo of the objective lens in the optical pickup 20.

The control unit 70 controls each element to write data to or read data from the optical disc. The optical drive unit 30 controls the optical pickup to read data from the optical disc 10. The laser diode in 20 is driven with reproducing power or the laser diode is driven with recording power for recording data on the optical disc 10.

In addition, the control unit 70 is based on the RF signal detected by the optical pickup 20 and output from the R / F unit 50 and the FG signal generated in the spindle motor 11, the servo / The drive unit 60 is controlled to drive the spindle motor 11 to rotate the disk 10 at a desired speed, and the spindle motor 12 to drive the optical pickup 20 to a desired position. A current is applied to an actuator supporting the objective lens in the optical pickup 20 to perform focusing servo and tracking servo.

The interface 80 may be a USB, Serial ATA (SATA) interface, or the like. The interface 80 may connect an ODD to a host to exchange data or commands. In the case of an external ODD, power may be supplied from the host through a USB interface. .

When a drive voltage of a predetermined magnitude (THsled + / Thsled-) or more is input to the sled motor according to a user's request to track jump or move to another track, the drive voltage limited to THspd is applied to the spindle motor by the logic circuit of FIG. The current applied to the ODD is limited to below THcurrent.

Accordingly, in the case of an external ODD powered through a USB line, the logic circuit of FIG. 3 enables stable power management without driving the sled motor and the spindle motor in time by software. .

Meanwhile, in the case of the embedded ODD or the embedded ODD but the power is independently supplied, the logic circuit of FIG. 3 may not be applied because the power is stably supplied. That is, in the case of an external ODD, the controller 70 may determine whether to operate the logic circuit of FIG. 3 based on whether the power is independently supplied from the outside, not the interface 80. The logic circuit of FIG. 3 may be operated when only the interface 80 is connected without an external power supply, and the logic circuit of FIG. 3 may not be operated when it is detected that power is supplied from the outside.

The above-described preferred embodiments of the present invention are disclosed for purposes of illustration, and those skilled in the art can improve, change, and substitute various other embodiments within the technical spirit and scope of the present invention disclosed in the appended claims below. Or addition may be possible.

11: spindle motor 12: sled motor
20: optical pickup 30: optical drive unit
40: digital signal processing unit 50: RF unit
60: servo / drive unit 70: control unit
80: interface

Claims (8)

A drive method for an optical disc apparatus, characterized in that the magnitude of the drive signal of the rotary motor for rotating the optical disc is limited with reference to the drive signal of the transfer motor for moving the optical pickup in and out. The method of claim 1,
And when the absolute value of the drive signal of the transfer motor is greater than the first value, limiting the drive signal of the rotary motor to a second value. The method of claim 2,
Wherein the first value is set larger than a drive signal applied to the transfer motor when the laser beam radiated from the optical pickup is moved outward along a spiral track formed in the optical disc. Driving method. The method of claim 3, wherein
The second value is set in consideration of at least one of a magnitude of power applied to the optical disk device, a maximum driving voltage applied to the transfer motor, and a driving voltage required to rotate the optical disk at a predetermined rotation speed. A drive method in an optical disk device. A transfer motor for moving the optical pickup in and out of the periphery;
A rotating motor for rotating the optical disk; And
Compare the absolute value of the drive signal of the transfer motor with the first value, compare the drive signal of the rotary motor with the second value, and limit the drive signal of the rotary motor to the second value based on the comparison result. An optical disk device comprising a logic circuit for performing. 6. The method of claim 5,
It further comprises an interface for connecting with the host,
And said logic circuit operates only when power is supplied through said interface. 6. The method of claim 5,
And wherein the first value is set larger than a drive signal applied to the transfer motor when the laser beam radiated from the optical pickup is moved outward along a spiral track formed in the optical disc. 8. The method of claim 7,
The second value is set in consideration of at least one of a magnitude of power applied to the optical disk device, a maximum driving voltage applied to the transfer motor, and a driving voltage required to rotate the optical disk at a predetermined rotation speed. Optical disk device.

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