KR0150814B1 - Data access method of compact disk - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data access method of a compact disc for quickly finding and playing desired data on a disc such as a compact disc player (CDP) or a compact disc ROM (CD-ROM). To memorize the time data corresponding to the track, move the track by 4 ^N or 4 ⁿ according to the difference between the memorized time data and the time data of the track where the data to be accessed is located to find the location of the decitta to access. This improves product performance by reducing data access time.

Description

How to Access Data on Compact Disks

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data access method of a compact disc. More specifically, a compact disc is provided for quickly finding and playing desired data on a disc such as a compact disc player (CDP) or a compact disc ROM (CD-ROM). To a data access method.

In general, data access of a compact disc causes the laser to be directed to the disc through the lens of the pickup device, and reads the data of the reflected laser to move to the desired position. At this time, the method of moving the pickup device to the position where the desired data is located stops when it comes to the position of the desired data by reading data for each position while moving the track which is a bunch of data contained in the disc by a certain amount.

The time it takes to access the data in this way is typically about 0.5 seconds. Therefore, faster access time is required.

It is an object of the present invention to implement a method for faster access of data in view of this point.

That is, the invention for accessing data at a desired position on a compact disc is a first step of storing time data for each track from the inside of the disc in accessing desired data by moving each track of the compact disc to a data group track. And a second step of accessing the target data at a close distance when the difference between the time data of the current position of the pickup apparatus and the time data of the access target position is less than an arbitrary time; and the time data and access of the current position of the pickup apparatus. And a third step of accessing the target data at a distant distance when the difference between the time data at the target position is more than a predetermined time.

1 is a basic time data memory principle and operation flowchart for the present invention, (a) is a principle diagram, (b) is an operation flowchart

2 is a data access principle and an operation flowchart according to the present invention, where (a) is a principle diagram and (b) is an operation flowchart.

* Explanation of symbols on main drawings in the drawings

1: disc 2: spindle motor

3: pickup device

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

Fig. 1 shows a principle and operation flowchart for storing time data for each track for data access of the present invention.

(a) is a principle diagram. When the disk 1 first enters the deck apparatus, a task of preliminarily storing time data at a predetermined interval is performed. That is, after the pickup device 3 is moved to the inside of the disk 1 by the drive of the spindle motor 2, the number of tracks is calculated from the inside to the outside, and the time data for each fixed number of tracks is stored. As a result, it is possible to check how many tracks are in the disc 1, and by using the time data for each fixed track in advance, it is used as data when accessing the actual data.

FIG. 1B is a flowchart illustrating the operation thereof.

First, when the disc is loaded into the deck apparatus (S1), the pickup apparatus is moved into the disc (S2). The pickup apparatus checks whether the movement to the inside of the disc is completed (S3), and when it is completed, the pickup apparatus is moved out of a predetermined track (a), for example, 300 tracks (S4), and the time data at that time is stored (S5). . After repeating these steps S4 and S5 and reaching the end of the disc 1 (S6), the pick-up device to be moved is stopped (S7).

Since the time data is stored for every 300 tracks as described above, the track of the data to be accessed can also be quickly found by the stored time data.

Referring to FIG. 2 in this regard, this is a principle and operational flowchart for finding data to access using stored time data.

(a) is a principle diagram in which the time data of each track is read from the position (Y) where the current pickup device is located to the position (X) where the target data to be accessed is read at any predetermined time, for example, 2 seconds. If it is below, it judges with a short distance, and if it is more than 2 second, it judges with a long distance. If it is less than 2 seconds, it moves to the position where the target time data exists by ^4N tracks. The 4th quarter track of ^4N moves to the position where the target time data is located, passing the position where the target time data is located.

It continues to move quarterly and checks if N has passed the target time data by zero, that is, one track, and if it is over, it is at the beginning of the track to be accessed and stops the pickup device. Then, the data is read.

If it is 2 seconds or more, it moves to the position where target time data exists by ^4N tracks. Similarly, the process is performed in the same manner as described above to check whether n is zero, that is, one track so as to pass the target time data, and if it is excessive, it is at the beginning of the track to be accessed. Then, the data is read.

Where N and n are even and zero, and n is greater than N. Also, 4 ^N should be smaller than the total number of tracks on the compact disc.

For example, for short distances, N starts at 2, and moves in the order of 16 tracks, 4 tracks, 1 track, and for long distances, n starts at 4, 256 tracks, 64 tracks, 16 tracks, 4 tracks, 1 track. Move in order.

For example, look at the operation sequence as shown in (b) as follows.

That is, it is determined whether or not the difference between the time data of the track currently having the pickup device and the time data of the target track to be accessed is 2 seconds or less (T1). If it is 2 seconds or less, it determines that it is a short distance and moves 16 tracks (T2). Then, it is determined whether the target time data has passed (T3), and if not, the above step (T2) is repeated, and if it has passed, four tracks are moved toward the position where the target time data is located (T4).

In addition, it is determined whether the target time data has passed (T5), and if it has not passed, the above step (T4) is repeated, and if it has passed, one track is moved toward the position where the target time data exists (T6). After moving in this step (T6), check whether the target time data has passed (T7). If it has not passed, repeat this step (T6), if it has passed, complete the pick-up move (T8) and access the data at that position. do.

In step T1, if the difference between the time data of the track currently being picked up and the time data of the target track to be accessed is two seconds or more, it is determined that the distance is far and 256 tracks are moved (T9). Then, it is determined whether the target time data has passed (T10). If it has not passed, this step (T9) is repeated, and if it has passed, 64 tracks are moved (T11). Also, it is determined whether the target time data has passed (T12), and if it has not passed, repeats this step (T11), and if it passes, repeats these steps (T2 to T8).

As a result of this, the access time is reduced to 0.2 seconds.

As described above, according to the present invention, the data access time for finding and playing desired data on the disc is shortened, and furthermore, the product performance is improved.

Claims (5)

Accessing desired data by moving each track of the compact disc to a data group track, the first step of storing time data for each track from the inside of the disc; A second step of accessing the target data at a close distance when the difference between the time data of the current position of the pickup apparatus and the time data of the access target position is less than an arbitrary time; And a third step of accessing the target data at a distant distance when the difference between the time data at the current position of the pickup apparatus and the time data at the access target position is greater than an arbitrary time. 2. The method of claim 1, wherein the first step includes moving the pickup device to the inside of the disc when the disc is loaded, and moving the pickup device out of a predetermined track (a) to obtain time data at each track (an) position. And storing the memory and stopping the pickup device when the pickup device is moved to the end of the disk. 2. The method of claim 1, wherein the second step includes accessing data over short distances, and with a number of tracks reduced by one quarter past the target time data while moving the track by 4 ^N toward the target time data location. Repeating the step of moving again, if the movement track becomes one track and the target time data is exceeded, it is determined that the start position of the corresponding access target time data and the pickup device is stopped. 2. The method of claim 1, wherein the third step is to access data at a distance and to reduce the number of tracks by one quarter when the target time data is passed while moving the track 4 ^N toward the target time data location. Repeating the step of moving again, if the moving track becomes one track and the target time data is excessive, it is determined that it is the start position of the corresponding access target time data, and the pickup apparatus stops the pickup device. 5. A method according to claim 3 or 4, wherein N and n are zero and even, wherein n is greater than ^N and 4 ^N is less than the total number of tracks in the compact disc.