KR100595497B1 - Digital Information Storage Media and Its Prevention Methods - Google Patents

Abstract

The present invention relates to an information storage medium storing digital information and a method of preventing duplication of the medium.

In the digital information storage medium of the present invention, at least one predetermined section becomes a non-serving section in which the whole is a mirror area or a valley area, and thus access for copying is impossible.

Description

Digital Information Storage Media and Its Prevention Methods

The present invention relates to an information storage medium storing digital information and a method of preventing duplication of the medium.

Digital information storage media have been developed and distributed such as commercially available CDs and DVDs that store a large amount of information compared to CDs. Such digital information storage media are classified into non-recordable reproduction-only and rewritable media. In the former type, there are ROM types such as CD-ROM and DVD-ROM. In the latter type, CD-R can be written once depending on the number of rewritable times. , WORM (Write Once Read Many) type such as DVD-R, RAM type such as CD-RW and DVD-RAM that can be repeatedly recorded. In the digital information storage medium, audio / video data and software are modulated and recorded into digital information. In general, when information is represented in an analog form, when the information is represented in a digital form, the information is easily reproduced because there is no deterioration of information due to transmission characteristics. In fact, a storage medium such as a CD-ROM or a DVD-ROM can easily copy an original disk by using a driver such as a CD-R or a CD-RW which a general user possesses. For this reason, it is now a big problem in copyright. Therefore, it is urgently needed to prohibit the duplication of digital information stored in the original or to judge the duplication. As a copy protection method, there are methods disclosed in US Patent 5418852, US Patent 5661800, US Patent 5513260 and the like. The copy protection method disclosed in U.S. Patent 5418852 is a method of determining whether to copy using a 'dummy defective sector', which is a kind of bad sector, but scans without recognizing the bad sector, such as a CD-ROM driver. In the scanning device, there is a problem in that the duplication copy cannot be determined only by the address of the bad sector. The copy protection method disclosed in U.S. Patent No. 5661800 determines whether a copy is made by using a difference between a physical address and a logical address, but a recent copying device is copied as it is and the difference between a physical address and a logical address in a copy. There is a problem that can not respond to the absence. In addition, the copy protection method disclosed in US Patent 5513260 is for preventing illegal copying by using an authenticating signature, and this method has a disadvantage in that a separate encryptor is installed in a driving device.

Since illegal copying of general users copies the original disk using their own CD-R or CD-RW drive, such illegal copying software detects the difference between the original disk and the copy disk and It can be prevented by judging. On the contrary, in recent years, due to the development of the copying device, the encoding / decoding process can be omitted, and the copying can be made identical to the original in a 1: 1 correspondence, thereby facilitating mass illegal copying. Mass replication using such a copying device transfers the signal detected from the original disk by optical pickup to the disk to be copied as it is, and this process is used to produce a stamper for disk copying. impossible.

Accordingly, an object of the present invention is to provide a digital information storage medium for blocking illegal copying in advance.

Another object of the present invention is to provide a method of preventing copying of a digital information storage medium to facilitate discrimination between an original and a copy.

In the digital information storage medium of the present invention, at least one predetermined section becomes a non-serving section, thereby making it impossible to access the copy. Here, the non-serving section is an area where the tracking servo, the spindle servo, the sled servo, the focusing servo, and the like are impossible, thereby preventing illegal duplication in hardware.

In order to achieve the above objects, the digital information storage medium according to the present invention is characterized in that at least one or more of the servo non-sections are formed in the mirror area or the valley area.

According to the present invention, a method of preventing copying of a digital information storage medium includes reading position information corresponding to a position after a non-serving period in a storage medium in which at least one non-serving section is formed, and whether the read position information is equal to a specific value. Comparing the step, and if the location information is not a specific value, determining the storage medium as a copy.

Other objects and features of the present invention in addition to the above objects will become apparent from the description of the embodiments with reference to the accompanying drawings.

Referring to Figures 1 to 4 will be described a preferred embodiment of the present invention.

1 is a view showing a digital information storage medium of the present invention.

In the configuration of Fig. 1, in the digital information storage medium of the present invention, at least one or more non-serving sections 2 are formed between tracks in which valid data is recorded. In general, a driving device of a digital storage medium includes an autotracking function for automatically searching for a next position when a position cannot be determined while scanning a track. The non-serving section 2 is an area where tracking is impossible so that the light beam cannot follow the track center line, and is set to a width larger than the next position where auto-tracking cannot be found. For this purpose, the entire non-servo section 2 consists of a track of a mirror or groove. As can be seen from the figure, the non-servo section 2 is formed with a width of approximately 3 track pitches (TP). Valid Fourteen Modulation (EFM) data is a pit representing binary information on the first and seventh track centerlines (Tn, Tn + 6) adjacent to the non-serving section (2). ) Is recorded in the form. In addition, a dummy track exists between the non-serving section 2 and the tracks on which the effective EFM data is recorded. Signals indicating the presence of the section 2 are recorded in the form of pit. When the dummy tracks are immediately adjacent to the non-serving section 2, some data adjacent to the non-serving section 2 may not be read, thereby preventing the dummy track.

A drive system for the storage medium is provided with a servo system that allows the light beam to follow the signal track center of the disk. This servo system consists of tracking, focusing, spindle and sled servos, and if any one of them does not operate normally, the data recorded on the disk cannot be read. . Spindle servo causes the disk to rotate by driving the spindle motor on which the disk is seated at a fixed speed. The tracking servo causes the light beam to follow the track centerline where the EFM data is present and the focusing servo causes the focus of the light beam following the track centerline to match the disk plane. The sled servo serves to move the optical pickup unit itself to generate light according to the tracking error signal. When the light beam is irradiated to read the information recorded on the digital information storage medium, the light beam follows the track center line in the form of a light spot. The light spots focused on the disk face are converted back to an electrical signal by a photodetector backing the optical path from the disk.

2 shows light spots focused on the storage medium shown in FIG. 1, and FIGS. 3A to 3C show the state of light irradiated to the photodetector according to the position of the light spot.

2 to 3C, when an optical spot is formed on the first and seventh track centerlines Tn and Tn + 6 in which the EFM data is recorded, the tracking error signal detected by the optical spot and the EFM data are included in the EFM data. The servo system operates normally according to the EFM servo signal. On the contrary, when an optical spot is formed on the non-serving section 2, the servo system malfunctions or the operation itself is impossible. When the light spot accurately follows the center of the track centerline, the reflected light beam of the light spot is evenly distributed to the first to fourth photodetectors A, B, C, and D of the quadrant photodetector 4 as shown in FIG. 3B. Is investigated. At this time, the tracking error signal is derived as a value corresponding to the difference between the sum signal of the first and fourth photodetection pieces A and D and the second and third photodetection pieces B and C. That is, the tracking error signal Te = (A + D)-(B + C). As described above, when the light spot normally follows the tracking center line, light is uniformly irradiated onto the photodetectors A, B, C, and D of the quadrant photodetector 4 so that the tracking error signal Te is '0'. Becomes On the contrary, when the light spot is eccentric from the tracking center line to the inner circumferential side or the outer circumferential side, each of the photodetecting pieces A, B, C, and D of the four-segment photodetector 4 is irradiated with uneven light so that the tracking error signal Te Is detected at either the positive (+) level or the negative (-) level. That is, when the light spots 33 ₂ are eccentric to the inner circumferential side from the first track center line Tn on the first track center line Tn on which the EFM data is recorded, as shown in FIG. 3C, the first and fourth light detections are performed. The amount of light increases in the pieces A and D, and the amount of light decreases in the second and third light detecting pieces B and C. At this time, since the light amount becomes A + D> B + C, the tracking error signal Te is detected as a positive polarity level value. If the light spot 33 ₁ is eccentric to the outer circumferential side from the track center line Tn on the seventh track center line Tn + 6 on which the EFM data is recorded, it can be seen in FIG. 3A. The amount of light is increased in (B, C), and the amount of light is decreased in the first and fourth light detection pieces (A, D). At this time, since the amount of light becomes B + C> A + D, the tracking error signal Te is detected as a negative polarity level value. The tracking servo system controls to move the light spot to the outer circumferential side when the tracking error signal value is the positive polarity level, and to control the actuator mounted with the objective lens to move the light spot to the inner circumferential side when the tracking error signal value is the negative polarity level. do. At this time, the sled servo system transfers the optical pickup unit itself to the inner circumferential side or the outer circumferential side.

As such, in the first and seventh track centerlines (Tn, Tn + 6) in which valid EFM data is recorded, the servo system is normally driven so that the optical spot follows the track centerline on the spiral and reads information, but the servo cannot be operated. In (2), the servo system malfunctions or the drive itself becomes impossible. When the light spots 11 ₁ , 11 ₂ , 11 ₃ , 11 ₄ are focused on any one of the third to fifth track center lines Tn 2 to Tn 4 of the tracking section, the light spots 11 ₁ , 11 ₂ , 11 ₃ , 11 ₄ ) Since there is no concave-convex shape in the effective diameter of ₄ ), the light traveling backwards through the optical path has the same amount of light detected in either of the first and fourth light detecting pieces A and D, and the tracking error signal becomes "0". The sled error signal is also "0". The tracking servo system then controls to maintain the current position of the light spots 11 ₁ , 11 ₂ , 11 ₃ , 11 _{4 in} the radial direction of the disc, so that the light spots 11 ₁ , 11 ₂ , 11 ₃ , 11 ₄ It will rotate repeatedly concentrically from the current position. In addition, since the spindle servo system does not record EFM data including the EFM servo signal in the non-serving section 2, the spindle motor is runaway or stopped. Accordingly, when the non-serving section 2 is accessed in order to copy the original disk in which the non-serving section 2 exists, the servo system operates abnormally, so that no further copying is possible, so that the copying itself can be blocked in advance. do.

On the other hand, the original disc in which the non-serving section 2 exists includes the track of the non-serving section 2 that should be jumped so that the optical pickup can jump to the non-serving section 2 and access only valid tracks. It is played by the program with the number and the next start address after the jump.

Although copying of the original disk in which the non-servo section 2 exists is impossible, even if copying is possible, it is easy to determine whether or not the original.

4 is a flowchart illustrating a control procedure of a method of copying a digital information storage medium according to the present invention.

Referring to Fig. 4, when the disc is loaded into the driving device, the execution program is loaded and executed by the control means (for example, a microcomputer). The execution program searches for a specific file area corresponding to the position information after the original servo unavailable section 2 with respect to the disc currently accessed, and detects the position information of the specific file area (steps 21 and 22). The execution program then compares the start address (start address: hereinafter " specific address ") of the data area starting after the end of the original servo impossible section 2 with the position information detected on the currently suppressed disk. (Step 23) In step 23, if the detected location information is the same as the specific address value, the execution program determines the disc currently accessed as the original (step 24). If the detected location information is different from the specific address value, the copy is made. (Step 25).

That is, in the copy protection method of the digital information storage medium according to the present invention, since the non-serving section 2 does not exist in the copy, the position information of the copy corresponding to the position where the non-serving section ends in the original is different from the original. Copies will be determined using

As described above, in the digital information storage medium according to the present invention, at least one or more predetermined sections of the original disk are set to non-servo sections so that a separate device is not required to be installed in the driving device of the storage medium, and the manufacturing process of the storage medium is provided. In this case, an additional process for preventing illegal copying is not added, and illegal copying of a storage medium can be blocked in advance. In the copy protection method of the digital information storage medium according to the present invention, since a predetermined section of the original disk becomes a non-servo section, it is easy to distinguish between the original disk and the copy disk. Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 illustrates a digital information storage medium according to an embodiment of the present invention.

FIG. 2 is a view showing a light spot focused on the digital information storage medium shown in FIG.

3A to 3C are views showing a state in which the light spots shown in FIG. 2 are irradiated to the photodetector by traveling back to the optical path.

4 is a diagram illustrating a control procedure of a copy protection method of a digital information storage medium according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

2: Servo impossible section 4: Photodetector

Claims (3)

A digital information storage medium, characterized in that formed at least one servo non-section in the whole of the mirror area or the valley area. The method of claim 1, And the non-servo section is formed with a track width larger than the width of the track on which valid data is recorded. Reading position information corresponding to a position after the non-serving section with respect to a storage medium in which at least one non-serving section is formed; Comparing the read position information with a specific value; And determining the storage medium as a copy when the location information is not the specific value.