KR100300971B1 - Revolution per minute setting method of optical disc - Google Patents

Abstract

PURPOSE: A method for setting up the rotational speed of an optical disk is provided to realize the maximum processing speed in a section where data are written within the outermost circumference by setting up RPM(Revolution Per Minute) for each section of an optical disk. CONSTITUTION: A method for setting up the rotational speed of an optical disk comprises the steps of inspecting the position of the data written on an optical disk by reading a TOC(Table Of Content) region(100), deciding if the data in a process are placed within the innermost circumference in which processing at the maximum double speed is possible(105), rotating a spindle motor at an RPM corresponding to the value A(110), dividing the part in which maximum speed processing is possible into N sections(115), deciding if the data in a process are placed in a second section(120), rotating the spindle motor at a first RPM(125), deciding if the data in a process are placed in a second section(130), rotating the spindle motor at a second RPM(135), deciding if the data in process are placed in a (N-1)th section(150), and rotating the spindle motor at a (N)th RPM(160).

Description

Revolution per minute setting method of optical disc}

The present invention relates to a rotation speed setting method of an optical disk, and more particularly, to provide a rotation speed setting method of an optical disk for dividing sections of the optical disk to set the rotation speed differently according to each section.

A typical optical disc can only be used on one side, but the recording density is high enough to record data of up to 74 minutes and 42 seconds on 20,000 tracks and 6 billion feet. In addition, by using the constant rotation method (CAV: Constant Angular Velocity) as the rotation method of the optical disk, the linear velocity is increased at the outer circumference and the linear velocity is decreased at the inner circumference. Therefore, regardless of the data recorded on the disc, the speed is the fastest at the outermost circumference, that is, 70 minutes of play time.

As described above, when data within 70 minutes is recorded on the optical disc having the highest double speed in the 70-minute range, the maximum double speed is not realized and there is an inconvenient problem in that the performance of the optical disc cannot be fully exhibited.

The technical problem to be achieved by the present invention is to provide a method for setting the rotation speed of the optical disk to achieve the maximum double speed in the section in which data is recorded within the outermost circumference by dividing the sections of the optical disk and setting the rotational speed per minute.

1 is a flowchart showing a method of setting a rotation speed of an optical disk according to the present invention.

In order to solve the technical problem to be solved by the present invention, a method for setting a rotation speed of an optical disk is provided in a method of setting a rotation speed by dividing an optical disk on which data is recorded. A first step of checking whether data has been recorded within; And a second step of dividing the optical disc into a plurality of sections and setting different rotational speeds in each section if data is recorded within the outermost circumference of the optical disk in the first step.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a flowchart showing a method of setting a rotation speed of an optical disk according to the present invention.

The flow diagram shown in FIG. 1 reads the thiosi region to check the position of the data recorded on the optical disk 100, and determines whether the data currently being reproduced is located within the innermost circumference at which maximum double speed can be realized (105). Rotating the spindle motor at a rotational speed per minute corresponding to the A value (110), dividing it into N sections from the innermost to outermost circumference (115), where the maximum speed can be realized, and the data currently being reproduced is the first interval. Determining whether it is located at 120; rotating the spindle motor at a first rotational speed 125; determining whether the data currently being reproduced is located at the second section 130; rotating the spindle motor at a second speed Rotating at a rotational speed 135, determining whether the data currently being reproduced is located in a third section 140, and rotating the spindle motor at a third rotational speed Step 145, determining whether the data currently being reproduced is located in the N-th section 150, rotating the spindle motor at an N-1 rotational speed 155, rotating the spindle motor N-minutes Rotating at speed 160.

Next, the flowchart shown in FIG. 1 will be described.

First, the table of contents (TOC) area is read and the position of the data recorded on the optical disk is checked (step 100). Since the various information related to the disk is recorded in the thiosy area, the position of the data recorded on the disk is recorded. Can be checked. In particular, it is checked whether data is recorded within the innermost circumference of the optical disc.

In operation 105, it is determined whether the data currently being reproduced is located within the innermost circumference where the maximum speed can be realized. In order to find the position where the maximum speed can be realized, the position of the spindle motor can be investigated by investigating the performance, efficiency, reliability, and vibration of the spindle motor.

If the data currently being reproduced is located within the maximum inner circumference where the maximum speed can be realized, the spindle motor is rotated at a revolution revolution (RPM) corresponding to the value A (step 110). Since the rotation method of the optical disk is a constant speed rotation method, the speed is slower at the innermost circumference and faster at the outermost circumference. Therefore, at this stage, the maximum speed cannot be achieved at the rotational speed per minute, so it rotates at a constant rotational speed per minute for a speed lower than the maximum speed.

If the data currently being played is not located within the innermost circumference at which the maximum speed can be realized, the data is divided into N sections from the innermost circumference to the outermost circumference at which the maximum speed can be realized (step 115). The division section may be divided by time unit or track unit by user's selection.

It is determined whether data currently being reproduced is located in a first section of the N divided sections (120).

When the data currently being reproduced is located in the first section of the N division sections, the spindle motor is rotated at the first rotational speed (step 125). The rotational speed per minute at this time is the rotational speed per minute to achieve the maximum double speed.

If the currently playing data is not located in the first section of the N divided sections, it is determined whether the currently playing data is located in the second section of the N divided sections (step 130).

If the data currently being reproduced is located in the second section of the N division sections, the spindle motor is rotated at the second rotational speed (step 135). The rotational speed per minute at this time is the rotational speed per minute to achieve the maximum double speed. Here, when comparing the first rotational speed and the second rotational speed, the data density decreases toward the outer periphery and the rotation angle is constant, so the second rotational speed is lower than the first rotational speed.

If the currently playing data is not located in the second section of the N divided sections, it is determined whether the currently playing data is located in the third section of the N divided sections (step 140).

If the data currently being reproduced is located in the third section of the N division sections, the spindle motor is rotated at the third rotational speed (step 145). The rotational speed per minute at this time is the rotational speed per minute to achieve the maximum double speed. Here, when comparing the second rotational speed and the third rotational speed, the third rotational speed is lower than the second rotational speed.

In operation 150, it is determined whether the data currently being reproduced is located in the N-th section among the N divided sections.

If the data currently being reproduced is located in the N-th section among the N division sections, the spindle motor is rotated at the N-1 th revolution speed (step 155). The rotational speed per minute at this time is the rotational speed per minute to achieve the maximum double speed. Here, when comparing the N-2 rotational speed and the N-1 rotational speed, the N-1 rotational speed is lower than the N-2 rotational speed.

If the data currently being reproduced is not located in the N-th section of the N divided sections, the next section naturally becomes the N-th section, so that the spindle motor is rotated at the Nth revolution speed (step 160).

In this implementation, the maximum double speed can be realized at the maximum double speed from the innermost circumference to the outermost circumference of the optical disc, and the only other thing is the rotation speed per minute. The rotational speed per minute decreases as it goes outward.

As described above, according to the present invention, the division of the optical disk is divided and each rotational speed is set so that the maximum double speed can be obtained in the section in which data is recorded within the outermost circumference.

There is an effect that can be implemented.

Claims (2)

In the method for setting the rotational speed of the spindle motor by dividing the optical disk on which data is recorded, A first step of reading a thiosi area and checking whether data has been recorded in an area inside the outermost circumference of the optical disc; And A second step of setting an innermost circumference point (A point) at which the spindle motor can be realized at a maximum double speed; A third step of dividing the innermost circumference point (A point) to the outermost circumference point (B point) into a plurality of sections; And The fourth point is implemented at the maximum speed at the point A, and the fourth step of controlling the rotational speed of the spindle motor according to the amount of data recorded in each section between the point A and the point B and controlling at a constant speed in each section. To set the rotation speed of the optical disc. The method of claim 1, wherein the point A Rotation speed setting method of the optical disk, characterized in that the setting in consideration of any one or more of the performance, efficiency, reliability and vibration of the spindle motor.

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