KR100518535B1 - Variable disc control method for alleviating noise/vibration and disc driving apparatus thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable disk control method and a disk driving apparatus for reducing noise and vibration. The disk driving method for noise reduction when sequentially playing a disk on which data is recorded from an inner circumference to an outer circumference is based on a predetermined radius. A first step of driving the disc at a predetermined low speed rotation (RPM) speed in a smaller disc inner circumference; And a second step of driving the disk to increase the rotational speed as the radius increases on the outer circumference of the disk larger than the predetermined radius.

According to the present invention, it is possible to lower the noise and vibration during the drive of the disk without losing the transmission rate.

Description

Variable disc control method for alleviating noise / vibration and disc driving apparatus

The present invention relates to a disk drive method and apparatus, and more particularly, to a variable disk control method and a disk drive device for reducing the noise and vibration to reduce the noise and vibration in accordance with the increase in the double speed.

Generally, when driving an optical disk such as a CD-ROM, sector arrangement of the format as shown in FIG. 1 is performed. In order to reproduce a disc recorded in the sector format as shown in FIG. 1, an angular velocity constant recording method (CAV) is commonly used.

In most disc reproducing systems, the criterion for disc speed control is the outermost circumference of the data recording area in which data is recorded. 2 is a graph showing the angular velocity constant recording method (CAV) method. The CAV method drives the disc at the same rotational speed (RPM) from the inner circumference to the outer circumference regardless of the radius of the disk.

It is known that the aerodynamic noise of a disc is proportional to the fourth power of the rotation speed (RPM) when the drive such as a CD is controlled by the CAV method. However, since the general CAV driving method is implemented considering only the circuit performance of the disk, there is a need for a disk having an environmentally friendly driving performance that generates low vibration and noise.

An object of the present invention is to provide a variable speed control method of a disc and a disc drive device for applying a variable rotational speed during disc inner and outer circumference for low vibration and low noise.

In order to solve the above problems, a disk driving method for noise reduction when a disk on which data is recorded is sequentially reproduced from the inner circumference to the outer circumference thereof has a predetermined low speed rotation (RPM) speed at a smaller inner circumference of the disk. A first step of driving the disk; And a second step of driving the disk to increase the rotational speed as the radius of the disk is larger than the predetermined radius.

The method of claim 1, wherein the second step is implemented such that the rotational speed is characterized by a quadratic increase function curve as the radius increases.

2. The method of claim 1, wherein the first step is to drive the disc at a constant rotational speed less than 10% relative to the rotational speed of the angular velocity constant recording method (CAV).

In order to solve the above problems, a disk driving method for noise reduction in the case of sequentially reproducing a disk on which data is recorded from an inner circumference to an outer circumference is characterized by having a lower rotation speed than a predetermined reference rotation speed in a disk inner circumference within a predetermined radius. Driving the disk with one rotation function; Driving the disc as a second rotation function in which the rotational speed gradually rises to within 50% of the entire contents of the disc when the disc is driven beyond a predetermined radius; And driving the disc with a third rotation function in which the rotational speed rises sharply after 50% or more of the entire contents of the disc are read.

The first rotation function is preferably a rotation constant reduced by less than 10% compared to the rotation speed of the angular velocity constant recording method (CAV).

Preferably, the second rotation function and the third rotation function together become an incremental quadratic curve function.

In order to solve the above problems, the disc drive device drives a disc at a predetermined low speed rotation (RPM) speed on a disc inner circumference smaller than a predetermined radius when the disc on which data is recorded is sequentially played from the inner circumference to the outer circumference. In the outer periphery of the disk larger than the predetermined radius, the drive control unit for driving the disk to increase the rotation speed as the radius is characterized in that it comprises.

In order to solve the above problems, the disc drive device drives a disc at a predetermined low speed rotation (RPM) speed on a disc inner circumference smaller than a predetermined radius when the disc on which data is recorded is sequentially played from the inner circumference to the outer circumference. In the outer periphery of the disk larger than the predetermined radius, the drive control unit for driving the disk to increase the rotation speed as the radius is characterized in that it comprises.

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

3 is a flowchart illustrating a disk driving method for noise reduction according to the present invention.

The disk driving method for noise reduction when the disk on which data is recorded is sequentially played from the inner circumference to the outer circumference, drives the disk at a predetermined low speed rotation (RPM) speed on the smaller inner circumference of the disk based on a predetermined radius (step 300). ). That is, in the inner circumference of a certain radius or less, the disk is driven by a constant rotational speed CAV method, for example, reduced by less than 10% compared to the rotational speed of a typical angular speed constant recording method (CAV).

If the radius is larger than the predetermined radius, the disk drive control is performed in which the rotation speed increases as the radius increases (step 310). In this case, the control method may be implemented such that the rotational speed has a characteristic of a second-order increase function curve kr ² k (proportional constant, r; radius) as the radius increases.

The above-described method first lowers the rotational speed (speed) of the original disk drive speed than the normal CAV control to reduce noise and vibration at the start. Since the average human ear is insensitive to a slight increase in noise from the original noise, even if the speed of rotation of the disk is increased rapidly from a certain radius, the resulting noise and vibration do not significantly affect the user.

The above-described method can make up for the data rate loss due to the low rotational speed in the inner circumference so that the rotational speed is rapidly increased to drive the outer circumference at a higher speed than the reference CAV control, thereby recovering the rate loss.

In the method of FIG. 3, the disc is driven by a first rotation function having a rotational speed lower than a predetermined reference speed in the inner circumference of the disk within a predetermined radius. The disc may be described as a step of driving the disc with a slowly increasing second rotation function, and a step of driving the disc with a third rotation function in which the rotation speed rapidly increases after 50% or more of the entire contents of the disc have been read.

The first rotation function becomes a rotation constant reduced by less than 10% compared to the rotation speed of the angular velocity constant recording method (CAV). That is, CAV control is performed on the inner circumference of the disc within a predetermined radius with a lower rotation speed than the existing CAV control.

The second and third rotation functions together form an incremental quadratic function. In other words, the second rotation function becomes a rotation speed that rises slowly after a predetermined radius, and the third rotation function is implemented as a rotation speed of a rapidly rising form.

Such a method will be implemented in a disc drive device of a reproduction device for reproducing a disc such as a CD ROM.

4 is a graph comparing the disk drive control method and the conventional CAV control method of the present invention.

Since the variable RPM method of the present invention drives the disk at a lower driving speed than the conventional CAV method, it can reduce the disk vibration or noise at the start, and the disk is driven by driving the disk at a higher rotation speed than the general CAV method at the outer periphery. It is possible to fully recover data rate loss due to the slow driving speed in the system.

According to the present invention, it is possible to lower the noise and vibration during the drive of the disk without losing the transmission rate.

1 shows an example of sector arrangement of an optical disc such as a general CD-ROM.

2 is a graph showing the angular velocity constant recording method (CAV) method.

3 is a flowchart illustrating a disk driving method for noise reduction according to the present invention.

4 is a graph comparing the disk drive control method and the conventional CAV control method of the present invention.

Claims (12)

In the disc playback method when the disc on which data is recorded is sequentially played from the inner circumference to the outer circumference, A first step of driving the disc at a predetermined low speed rotation (RPM) speed on a smaller disk inner circumference based on a predetermined radius; And And a second step of driving the disk to increase the rotational speed as the radius increases on the outer circumference of the disk larger than the predetermined radius. 2. The method of claim 1, wherein the second step is implemented such that the rotational speed is characterized by a quadratic increase function curve as the radius increases. 2. The method of claim 1, wherein the first step is to drive the disc at a constant rotation rate less than 10% less than the rotation speed of the angular velocity constant recording method (CAV). In the disk driving method in the case where the disk on which data is recorded is sequentially played from the inner circumference to the outer circumference, Driving the disk with a first rotational function having a rotational speed lower than a predetermined reference rotational speed within the disk within a predetermined radius; Driving the disc as a second rotation function in which the rotational speed gradually rises to within 50% of the entire contents of the disc when the disc is driven beyond a predetermined radius; And And driving the disc with a third rotation function in which the rotational speed rises sharply after at least 50% of the entire contents of the disc are read. The method of claim 4, wherein the first rotation function is a rotation constant that is reduced by less than 10% compared to the rotation speed of the angular velocity constant recording method (CAV). 5. The method of claim 4, wherein the second rotation function and the third rotation function together become an incremental quadratic curve function. In the disk drive device, When the disc on which data is recorded is sequentially played from the inner circumference to the outer circumference, the disk is driven at a predetermined low speed rotation (RPM) speed on a smaller disk inner circumference based on a predetermined radius, and the larger the radius on the outer circumference of the disk larger than the predetermined radius. And a drive control unit for driving the disc to increase the rotational speed. The method of claim 7, wherein the drive control unit, A disk drive device, characterized in that the disk is driven such that the rotational speed is characterized by a quadratic increase function curve as the radius increases from the predetermined radius or more of the disk. The method of claim 7, wherein the drive control unit, And a disk drives the disk at a predetermined rotational speed less than 10% of the rotational speed of the angular velocity constant recording method (CAV) below a predetermined radius. In the disk drive device, When the disk on which data is recorded is sequentially played from the inner circumference to the outer circumference, the disk is driven by the first rotation function having a lower rotation speed than the predetermined reference rotation speed on the inner circumference of the disk within a predetermined radius, and the entire disk when the disk is driven beyond the predetermined radius. The drive control unit drives the disc with the second rotation function in which the rotational speed gradually rises up to 50% of the contents, and the third rotation function in which the rotational speed increases rapidly after 50% or more of the entire contents of the disc is read. Disk drive device comprising a. The disk drive apparatus according to claim 10, wherein the first rotation function is a rotation constant that is reduced by less than 10% compared to the rotation speed of the angular velocity constant recording method (CAV). 11. The disk drive apparatus according to claim 10, wherein the second rotation function and the third rotation function together become an incremental quadratic curve function.