KR100486289B1 - Method and apparatus for measuring unbalance of disc - Google Patents

Abstract

A method and apparatus for measuring the piece center of an optical disc are disclosed. The present invention is to accelerate the rotation of the disc with a read command to detect the rotational speed, the process of turning off tracking when the detected rotational speed of the disk reaches the target rotational speed, in the state in the tracking off And extracting a center error signal representing the amount of shaking of the actuator, and measuring the center of gravity of the disk by averaging the amplitude of the center error signal extracted in the above process.

Description

Method for measuring the eccentricity of a disk and its apparatus {Method and apparatus for measuring unbalance of disc}

The present invention relates to an optical disk device such as a CD-ROM, CD-R, CD-RW, DVD-RAM, and the like, and more particularly, to a method and apparatus for measuring the center of a piece of an optical disk.

As the personal computer becomes higher performance, the disk high speed rotation of the optical disk device is progressing to improve the data transfer rate. This high speed rotation involves the vibration problem caused by a single center disk. That is, it adversely affects the PC incorporating the optical disk device, generates noise, and causes inability to reproduce. In this case, a disk with a larger piece centering than an ordinary disk is called a piece centered disk. In this piece of central disk, disturbance caused by vibrations that cannot be handled by the servo occurs in the focusing and tracking loops. Therefore, in the drive of the optical disk, it is necessary to determine whether the mounted disk is a piece centered disk, and in the case of a piece centered disk, the speed should be limited to the maximum speed at which the normal drive operation can be performed according to the size of the disk center amount.

As a countermeasure for such a piece of central disk, a method of mounting an automatic balancing mechanism composed of a circumferential guide and a sphere rotating on the guide has been proposed. According to this structure, it is comprised so that a sphere may be automatically corrected in the position which a sphere cancels a piece center when a spindle motor rotates. On the other hand, a method of detecting vibrations during rotation of a piece centered disk using an acceleration sensor has also been proposed.

However, in the case of the automatic balancing mechanism, the correction may be incomplete due to the slide friction between the sphere and the guide, and in the worst case, there is a disadvantage of generating the piece center on the disk without the piece center. In addition, the need for high-precision guides and spheres also contributes to the cost increase. In the case of using the acceleration sensor, an increase in cost is inevitably accompanied.

The technical problem to be achieved by the present invention is to measure the center of gravity piece by using the center error signal in the optical disk drive device for playing and recording optical disks such as CD-ROM, CD-R, CD-RW, DVD-RAM, etc. The present invention provides a measuring method and an apparatus thereof.

In order to solve the above technical problem, the present invention provides a disk piece center measurement method,

Accelerating the rotation of the disc with a read command to detect the number of revolutions thereof;

Turning off tracking when the number of revolutions of the detected disk reaches the target number of revolutions;

Extracting a center error signal indicating an amount of shaking of the actuator while tracking is turned off in the above process;

And measuring the amount of eccentricity of the disk by averaging the amplitude of the center error signal extracted in the above process.

In order to solve the above other technical problem, the present invention is a disk eccentricity measuring apparatus,

Pickup means for reading an optical signal from the disc by incorporating an actuator for focusing and tracking;

RF amplifying means for extracting a center error signal corresponding to the amount of shaking of the tracking actuator of the pickup means;

When the host's read command is applied, the disk rotation is accelerated to count disk pulses by counting pulse signals generated from the spindle motor, and the disk eccentricity is calculated by averaging the amplitude of the center error signal extracted from the RF amplifying means. And control means for detecting.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is an overall block diagram of an optical disk drive apparatus for measuring the piece center of a disk according to the present invention.

First, the center error used in the present invention is a signal indicating the amount of shaking of the tracking actuator (pickup lens) when the feed motor is driven, for example, when the DC or the stepping motor is moved. It is a signal to be located at the center.

Referring to FIG. 1, the pickup 120 incorporates an actuator for focusing and tracking, and reads an optical signal from a disk 120 storing data.

The RF amplification unit 130 converts the optical signal output from the pickup 120 into an electrical signal, extracts a servo signal and modulation data for performing a servo, and outputs a focus error signal and an optical signal from the optical signal output from the pickup 120. The tracking error signal is detected, and the center error signal corresponding to the amount of shaking of the tracking actuator built in the pickup 120 is extracted.

The DSP unit 140 demodulates the modulated data extracted from the RF amplifier 130, removes additional data while correcting an error by performing ECC, and according to the lens up and down commands generated by the controller 150. Generates a signal to drive the lens of the pickup (120).

The servo unit 170 receives information necessary for servo control from the RF amplifier 130 and the controller 150 and applies a servo signal to the spindle motor 180.

The spindle motor 180 rotates the disk at a constant speed according to the servo control signal applied from the servo unit 170 and generates an FG pulse signal.

The controller 150 controls the pickup 120, the RF amplifier 130, and the DSP unit 140 according to a control command of a host. In particular, the controller 150 counts the FG pulse signal from the spindle motor 180 to disc. The number of revolutions is detected, and the center of gravity of the disk is detected by measuring the amplitude of the center error signal corresponding to the amount of shaking of the tracking actuator extracted from the RF amplifier 130.

The storage unit 160 includes a program for controlling the controller 150 and various parameter values.

Figure 2 is a flow chart showing a piece center measurement method of the disk according to the present invention.

First, when a disc is inserted into the drive (step 212), the focus and tracking servo are started to perform an initial operation of setting various parameters such as tracking error gain, focus error gain, and RF gain (step 214).

Subsequently, the TOC information is read (step 216), and the read-in operation is performed, and the terminal waits in a pause state for receiving a command from the host (step 218).

Subsequently, upon receiving the first read command from the host, the disk starts to accelerate the rotation (step 224).

Subsequently, the rotation speed of the disk is detected from the FG pulse signal generated by the spindle motor 180, and it is checked whether the disk rotation speed reaches a target rotation speed corresponding to the maximum vibration frequency of the deck (226). Here, the resolution is the most problematic in measuring the center of gravity using the center error. Distinguish between discs without a flank centroid and discs with a flank centroid. Therefore, the maximum vibration frequency of the deck is used for maximum disc discrimination. In other words, the resolution is maximum when the disc is rotated at the maximum vibration frequency of the deck. This means that when the disc is rotated at the maximum vibration frequency of the deck, the discriminant force between the disc without the piece centered component and the piece centered disk is maximized. Therefore, the maximum vibration frequency of the deck is measured beforehand.

Then, when the disk speed reaches the target speed, the tracking servo is turned off to reduce the influence of eccentricity or other disturbance and to measure only pure lens shake caused by deck vibration or vibration of the spindle axis (step 228).

Subsequently, the amplitude is measured by sampling a center error signal representing the amount of shaking of the actuator while the tracking servo is turned off (step 232). Here, measure the amplitude of the center error signal that occurs during one disc revolution. Also, for the reliability of the data, the amplitude of the center error is measured about 4 times and the average value of the amplitude is calculated (step 234). As a result, the mean value of the amplitudes corresponds to the central volume of the piece.

Subsequently, the eccentric disc is determined by comparing the amplitude of the measured center error signal with a predetermined threshold value, and when the disc is determined as the eccentric disc, the rotation speed of the disc is controlled according to the measured amount of eccentric center (step 236).

As shown in FIGS. 3 and 4, the normal disc amplitude (0.18 V) and the amplitude (0.56 V) of the center error signal of the 1.0 g cm disk are about three times different.

5 is a diagram showing the distribution of the eccentricity of the normal disc and the 0.3-1.0 g.cm disc by using the eccentric center measuring method of the present invention. From the measurement distribution diagram of FIG. 5, the eccentricity measuring method using the center error signal has the discriminating power as a eccentric disk.

The present invention is not limited to the above-described embodiment, and of course, modifications may be made by those skilled in the art within the spirit of the present invention.

As described above, according to the present invention, since the present invention utilizes the center error occurring in the actuator of the optical pickup, there is no need to add any special external device. In other words, it is possible to reduce the unit cost by determining the piece center disk and limiting the speed without additional cost increase, and by reducing the vibration and noise caused by the high-speed rotation by measuring the accurate piece center. It also saves lead-in time by measuring the piece center when it reaches maximum speed by the first lead command rather than measuring the piece center when it is lead-in.

1 is an overall block diagram of an optical disk drive apparatus for measuring the eccentricity of a disk according to the present invention.

2 is a flowchart showing a method of measuring the eccentricity of a disk according to the present invention.

3 is a center error measurement waveform for a normal disc without eccentric components.

4 is a waveform of measuring a center error signal by applying the present invention to a 1.0g.cm disc.

5 is a diagram illustrating a measurement distribution chart of each eccentric disk using the eccentric measurement method of the present invention.

Claims (6)

In the disk piece center measuring method, Accelerating the rotation of the disk according to a read command by the host to detect the rotation speed; Turning off the tracking servo when the disk speed detected in the process reaches a target rotation speed corresponding to a predetermined deck maximum vibration frequency; Measuring an amplitude of a center error signal representing an amount of shaking of the actuator while the tracking servo is turned off in the above process; And measuring the amplitude of the center error signal by repeatedly measuring the amplitude of the center error signal and setting the average value of the amplitude to the amount of eccentricity of the disk. The method of claim 1, further comprising controlling a disk rotation speed according to the amount of eccentricity of the disc measured in the process. The method of claim 1, wherein the amount of eccentricity of the disc is measured at a maximum vibration frequency of the deck. The method of claim 1, wherein the amount of eccentricity of the disc is measured when the target rotational speed is reached by a first read command. The method of claim 1, wherein the amount of eccentricity of the disc is measured by measuring an amplitude of a center error signal generated when the disc is rotated. In the disk eccentricity measuring device, Pickup means for reading an optical signal from the disc by incorporating an actuator for focusing and tracking; RF amplifying means for extracting a center error signal corresponding to the amount of shaking of the tracking actuator of the pickup means; When the host's read command is applied, the disk rotation is accelerated to count the pulse signal generated by the spindle motor to detect the disk rotation speed. When the rotation speed reaches the target rotation speed, the tracking servo is turned off to the RF amplification means. And a control means for detecting the amount of eccentricity of the disk by the amplitude of the center error signal generated by the disk eccentricity measuring apparatus.