KR20160067308A - Method for managing failed disc in archive system using optical disc - Google Patents

Abstract

The present invention relates to a method for managing a failed disc in an archive system using an optical disc. According to an embodiment of the present invention, a method for managing a failed disc in an archive system using an optical disc is performed by an optical disc-based archive system that transfers an optical disc between a cartridge for storing optical discs and an optical disc drive and records data on an optical disc through the optical disc drive or reads data recorded on an optical disc. The method includes confirming whether the optical disc drive failed to read an optical disc, and moving, by the optical disc drive, a failed disc confirmed as a failure to the farthest slot among slots storing optical discs that are not failed discs in the cartridge. Further, the method includes updating information on the slot to which the failed disc is moved and a slot in which the failed disc is originally stored in a cartridge flash. Thus, an operator can easily extract failed discs from the cartridge without an additional job confirming information on the number of failed discs included in the cartridge, confirming the locations of the failed discs, and manually sorting out the failed discs.

Description

[0001] The present invention relates to a method for processing a failed disk in an optical disk-

The present invention relates to a method for processing a failed disk in an optical disk based archive system.

As video signal processing technology and data transmission technology are developed and large display devices are developed, viewers can view high-quality contents and the need to store high-capacity contents is increasing.

In recent years, cloud services have been enabled to put data on remote servers and use data anywhere on the network, and the storage capacity that cloud services provide to individuals is also growing.

In this way, a large-capacity server for storing and managing a large amount of data in a portal for providing a cloud service, a broadcasting station for providing a large amount of contents, a library, a government office, a bank, Is increasing. In accordance with this necessity, an archive system that can store and retrieve a large amount of data reliably at a low cost and quickly is being launched.

Archiving system is a kind of database which maintains and maintains the relation between data and keeps the collection and data of digital information in the form of digital information. It digitizes information that may be degraded or dispersed over time, And so on. It is meaningful not to simply accumulate information, but to organize and accumulate information effectively in various ways.

Up until now, archival systems have been the mainstay of tapes as storage media. However, a tape-based archive system has the problem of high data stability but low search speed and large space. Hard disk-based archive systems are also emerging and are excellent in that they can be searched quickly, but data reliability is poor.

In recent years, an archive system using an optical disk as a storage medium has emerged. An optical disk-based archive system can search more quickly than a tape-based archive system and can store data more reliably than a hard disk-based archive system There is an advantage that the space occupied by the tape and the hard disk can be reduced.

An optical disc-based archive system includes a cartridge for storing a plurality of optical discs, an optical disc drive for recording data on the optical disc or reading data from the optical disc, and an optical disc between the cartridge and the optical disc drive A picker robot which is a transfer device for transferring is separately provided to move the optical disc taken out from the cartridge horizontally and then loaded into the optical disc drive and unloaded from the optical disc drive by reading / And then pulled into the cartridge.

The optical disc-based archive system can be equipped with two cartridges and each cartridge can hold, for example, 250 optical discs. In one archive system, a cartridge containing an optical disc on which data is recorded is detached from the system And has mobility that can be mounted in other systems. That is, by separating only the cartridge containing the optical disc from the system and attaching it to the other system, a large amount of data contained in the optical disc of the cartridge can be easily transferred to another system.

In addition, the optical disc in the cartridge mounted in the archive system can be replaced. In addition, when the optical disc is damaged during the movement between the cartridge and the optical disc drive, or when data is written or read in the optical disc, A failed disc may occur and such a failed disc may be removed from the cartridge and filled with a new blank disc.

If a failure occurs in recording or writing data from an optical disc loaded in the optical disc drive, the failed optical disc is moved to the original slot position in the cartridge and data recorded on the optical disc It can be recorded on a new optical disk. However, in such a case, it may become difficult to distinguish the failed disk in the cartridge from the normal disk.

Accordingly, it is an object of the present invention to provide a method for effectively managing a failed disc in an optical disc-based archive system.

According to another aspect of the present invention, there is provided a method of managing failed disks in an optical disc based archive system, the method comprising: transferring an optical disc between a cartridge for storing a plurality of optical discs and an optical disc drive, A method for recording data on an optical disc, the method comprising: checking whether a disc has failed in the optical disc drive, the method being executed in an optical disc-based archive system for writing data to or reading data from the optical disc through the drive; And moving the failed disk identified as failed from the cartridge to a slot that is the most distant from the optical disk drive among the slots containing disks other than the failed disk.

In one embodiment, when data is recorded from a blank disc held in a slot closest to the optical disc drive among the slots containing empty discs in the cartridge, and then the recorded disc is moved to the original slot, If a failed disk occurs, the failed disk can be moved to the slot farthest from the optical disk drive among the slots containing empty disks in the cartridge.

In one embodiment, an empty disc loaded in the slot to which the failed disc has been moved is loaded into the optical disc drive, data to be written on the failed disc is recorded on the loaded empty disc, Lt; / RTI >

In one embodiment, the cartridge flash may update information about the slot from which the failed disk has moved and the original slot of the failed disk.

In one embodiment, when the failed disk occurs while reading the recorded data after loading the disk on which data has already been written to the optical disk drive, the failed disk is inserted into a slot To the first slot farthest from the optical disc drive and to move the disc in the first slot to the original slot of the failed disc.

In one embodiment, a disk with a slow read response time or a failed disk read test may be identified by the failed disk.

In one embodiment, when a disk is identified as a failed disk, the failed disk may be moved to another optical disk drive to again verify whether the disk failed.

Thus, it is possible to easily extract the failed disc from the cartridge without additional operation of selecting the failed disc separately.

Figure 1 illustrates an optical disk based archive system,
2 shows a mechanism for transporting an optical disc in an optical disc-based archive system,
FIG. 3 shows a state in which a failed disk is distributed in a cartridge when managing a failed disk according to a conventional method,
FIG. 4 illustrates a state in which a failed disk is distributed in a cartridge when managing a failed disk according to an embodiment of the present invention,
FIG. 5 illustrates a functional block diagram of an optical disc-based archive system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a failed disk management method in an optical disk based archive system according to the present invention will be described in detail with reference to the accompanying drawings.

In the optical disc-based archive system, a plurality of optical discs are stored in left and right cartridges, and a picker robot moving between the right and left cartridges removes the optical disc from the cartridge, And then the optical disk is loaded on the optical disk drive or unloaded from the optical disk drive and then moved to a state fixed on the body of the picker robot and put back into the cartridge, Or reads data from the optical disc.

Figure 1 shows an optical disk based archive system.

The optical disc-based archive system 100 includes a drive bay 10 in which a plurality of optical disc drives (ODD) are installed, a picker robot 20 for moving the optical disc, a cartridge 30 for storing a plurality of optical discs A robot transfer unit 40 for driving and guiding the picker robot 20 so as to move between the drive bay 10 and the cartridge 30, a plurality of cooling fans 40 for discharging heat generated in the optical disk drive, And a fan module 50 installed therein.

The drive bay 10 and the cartridge 30 are arranged symmetrically and the guide of the robot transfer section 40 is installed between the left and right drive bays 10 and the left and right cartridges 30, It is possible to move between the left and right drive bay 10 and the cartridge 30 along the longitudinal direction of the cartridge 30. [

For example, six optical disc drives can be installed in the drive bay 10, so that up to twelve optical discs can be loaded in the left and right drive bays to perform data recording or data reading operations at the same time.

The cartridge 30 can store, for example, 250 optical discs, so that up to 500 optical discs can be stored in the left and right cartridges 30 provided on both sides of the picker robot 20, May be detached from the archive system. The cartridge 30 is spaced behind the cartridge disk rack with the rear open so that the kicker arm of the picker robot 20 has sufficient penetration space to push the optical disk into the body of the picker robot 20 .

The cartridge key rod used to lock or unlock the cartridge 30 into the system passes through the disk center hole in the cartridge 30 so that when the cartridge 30 is outside the system, 30).

2 shows a mechanism for transferring an optical disc in two directions in an optical disc-based archive system.

2, the optical disc-based archive system 100 includes an X-directional optical disk drive (not shown) for loading / unloading (or loading / unloading) an optical disk into / from the optical disk drive or cartridge 30 of the drive bay 10 And transport in the Y direction for transporting and transporting the optical disk in the disk handling assembly, which is the body of the picker robot 20.

The Y directional transfer is performed by moving the optical disk contained in the disk handling assembly of the picker robot 20 to a desired optical disk drive in the drive bay 10 and a picker robot 20 The picker robot 20 is moved along a guide provided at the center between the left and right drive bays 10 and the left and right cartridges 30.

The guide may include a robot feed screw for driving the picker robot 20 back and forth and a robot feed motor for rotating the robot feed screw, and the picker robot may be connected to a bone or mountain of the screw, And a connection structure for converting the rotational motion of the screw into the linear motion in the Y direction.

The movement in the X direction is performed by an unloading mechanism in the optical disk drive of the drive bay 10, a rotational movement of the picker arm of the picker robot 20, and an actuator drive included in the disk handling assembly, A cartridge 30, and a device for moving the optical disk in the X direction in the disk handling assembly.

The picker robot 20 moves the disc in the cartridge 30 into the disc handling assembly as a body through the actuator included in the kicker arm and the disc handling assembly while detecting the position of the optical disc placed in the disc handling assembly, Direction so that the disk lies in the center of the body of the picker robot.

As described above, the archive system 100 uses a large amount of system resources to read data from the optical disc placed on the cartridge 30, and controls the picker robot 20 and the robot transfer transfer unit 40 to transfer data from the cartridge 30 It is possible to perform an operation of pulling out the optical disc (X direction feeding), moving to the drive bay 10 (Y direction feeding) and loading (X direction feeding) to the optical disc drive.

When moving a cartridge containing a plurality of optical discs to another archive system, the newly installed archive system sequentially transfers the optical discs in order to check the metadata of the optical discs contained in the cartridges, It requires a lot of system resources, is time-consuming, and can not respond to external data read or data write requests while reading the metadata.

In view of this, cartridge flash can be used to store information about the optical disc in the cartridge 30, including a list listing what is in each slot of the cartridge 30, a volume identifier for each disc, A simple history of the disc including the number of rewrites and the number of errors of the available discs, and may also include information about the files included in each disc.

On the other hand, when the cartridge 30 in which the empty disc is loaded is loaded in the archive system 100 and records user data, the archive system 100 is arranged such that, among the blank discs contained in the cartridge 30, A slot closest to the drive bay 10 in the cartridge 30 capable of accommodating an optical disk, for example, 250 optical disks contained in the slot is referred to as a slot 1000, and a slot farthest from the drive bay 10 is referred to as a slot 1249 It is possible to move the optical disk in the slot 1000 to the optical disk drive using the picker robot 20 and then record the data on the optical disk loaded in the optical disk drive. The recorded optical disc is moved to the original slot again.

When the recording of the data on the blank disk in the slot 1000 is completed, the empty disk contained in the slot 1001 is loaded into one optical disk drive in the drive bay 10 by the picker robot 20, Lt; RTI ID = 0.0 > 1001 < / RTI > As described above, data is sequentially recorded from the optical disc in the slot close to the drive bay 10.

If a recording failure occurs during data writing to the optical disc drive and the disc becomes unusable, that is, if a disc fails, the disc is moved to the original slot by the picker robot 20, The loaded blank disc is loaded into the optical disc drive, and the failed data is rewritten.

FIG. 3 illustrates a state in which a failed disk is distributed in a cartridge when a failed disk is managed according to a conventional method. In the case where an error occurs during data recording on a blank disk contained in the slot 1001 and the disk can not be used The failed disk is returned to the slot 1001 which is the original slot again, and the empty disk contained in the slot 1004 also has an error that can not be recovered during the data recording, so that the failed disk is returned to the slot 1004 originally. 1000, 1002, 1003, 1005, and 1006 contain discs on which data is recorded, and discs 1007 to 1249 contain empty discs.

Since the flash memory of the cartridge 30 stores a list listing what is in each slot, information on the slot containing the failed disk, the slot containing the disk in which the data recording is completed, and the slot containing the blank disk is confirmed through the cartridge flash .

If the failed disk is contained in the cartridge 30, the administrator or operator of the archive system 100 can remove the failed disk from the cartridge 30 and fill the empty disk, because the amount of data that can be stored in the cartridge 30 is reduced . However, in order to remove the failed disk, the contents of the cartridge flash must be checked through a computer or a server connected to the archive system 100, and the slot number containing the failed disk must be checked from the cartridge 30 containing the disk closely. It is also cumbersome to remove other disks that have been written incorrectly, not accidentally.

In order to solve this problem, when a disk failure occurs while data is being written to the optical disk from the optical disk drive, the failed disk can be moved to a predetermined position in the cartridge rather than the original slot of the cartridge. The failed disk can be moved to the slot located farthest from the optical disk drive.

FIG. 4 illustrates a state in which a failed disk is distributed in a cartridge when managing a failed disk according to an embodiment of the present invention. In this case, the first failed disk in the cartridge 30 is the slot farthest from the optical disk drive, That is, the 1249th slot, and the second failed disk is moved to the second farthest slot in the optical disk drive, that is, the 1248th slot. The disks on which data is recorded are filled in order from the slot 1000, which is the closest slot from the optical disk drive, and a blank disk is placed between the recorded disk and the failed disk.

5 is a block diagram of a functional block of an optical disc-based archive system to which the present invention is applied.

The optical disc-based archive system 100 includes a drive bay 10 for recording and reading data, a picker robot 20 for transferring an X-directional and an Y-directional transport of an optical disc, A robot 30 for driving the picker robot 20 in the Y direction and guiding movement of the picker robot 20, a processor, a memory, an operating system (OS), customized program code and hardware A control unit 60 for commanding or controlling other hardware in the system, and a network unit 70 for transmitting and receiving data and commands by connecting to a server or host in the form of a middleware.

The optical disc-based archive system 100 includes an interface unit including a connection terminal for transmitting and receiving data, such as a memory slot, USB, SCSI, E-SATA, Firewire, etc., and a controller for controlling the flow of data through the connection terminal And may transmit data to an external device connected via an interface unit, a USB memory, or the like.

The administrator can connect the archive device (library) through the middleware type server through the application installed in the operator terminal and control the archive device in the application. Library software for managing device operation can be installed in a single board computer (SBC) of the archive device.

The controller 60 executes the library software and is connected to the middleware and the application. The controller 60 verifies the performance of reading and writing of the optical disk drive included in the drive bay 10 according to an operator's command through the application, It plays the role of recording or reading the requested archive data or already archived data by using the optical disk drive.

The library software executed by the control unit 60 communicates with the server and / or the operator terminal via Ethernet through the network unit 70 to receive commands and data, and based on this, performs operations in the archive system, for example, Processing of requests for the diagnosis and data access and storage of the archive system, such as selection, movement, loading into the optical disk drive, and drive of the optical disk drive through the picker robot 20.

The control unit 60 controls the picker robot 20 in response to a data recording request in a state where a new cartridge 30, that is, a cartridge 30 containing only a blank disc, is mounted in the archive system 100, In the slots closest to the drive bay 10 in which the drive is disposed, that is, a blank disc contained in the slot 1000 in FIGS. 3 and 4 is moved to the optical disc drive, and the optical disc drive is controlled to move the requested data And when the data recording is completed, the picker robot 20 can be controlled to move the optical disc to the original slot.

In this way, the control unit 60 can sequentially record data from the optical disc in the slot closest to the drive bay 10, and return the recorded optical disc to the original slot. A disk on which data is recorded is filled from a slot near the drive bay 10 in the cartridge 30 and a blank disk is put in a slot far from the drive bay 10 after the last disk on which data is recorded.

When a failure that can not be recovered occurs while data is being written to the blank disk, the controller 60 moves the failed disk to the slot farthest from the drive bay 10 without moving it to the original slot, If the first failed disk occurs in the first disk 30, the disk is moved to the slot 1249 and the blank disk in the slot 1249 is loaded in the optical disk drive to record the data to be written to the failed disk. When the data recording ends, It can be moved to the original slot.

Similarly, if a second failed disk occurs in the corresponding cartridge 30, the failed disk is moved to the most distant slot in the drive bay 10, that is, 1248 slots among the slots containing empty disks in the corresponding cartridge 30, The blank disc in the slot is loaded into the optical disc drive to store the data that failed to record.

As described above, the failed disc is filled in the cartridge 30 in the direction from the slot farthest from the drive bay 10 toward the drive bay 10 in order.

When data is recorded on the optical disc contained in the cartridge 30 or a position of the disc is changed due to the occurrence of a disc failure, the controller 60 updates the information about the disc contained in each slot in the cartridge flash. At this time, A slot containing a blank disc, information about a slot containing a recorded disc, and the like can be stored in the cartridge flash.

The controller 60 determines a slot to which the corresponding failure disk is to be moved based on the information stored in the cartridge flash when a failure occurs while recording data on the optical disk and controls the picker robot 20 to move the failed disk Moving to a determined slot, and moving a blank disc contained in the determined slot to the optical disc driver, thereby recording failed data.

Even if the reading of the data on the disk fails while the disk containing the data requested to be read out among the disks contained in the cartridge 30 is moved to the optical disk drive and the data is being read, It is possible to move the optical disk in the slot to the farthest slot in the drive bay 10 and move the optical disk in the slot to the original slot of the failed disk. In this case, the cartridge flash is updated to store the position of the failed disk, Lt; / RTI > can also be updated.

In order to ensure data reliability of the recorded disc, the controller 60 performs a disc quality check operation to determine whether the disc on which the data is recorded is readable, And it is possible to confirm whether or not the corresponding disk has failed through the whole data reading test and the SER (Symbol Error Ratio) measurement.

The control unit 60 performs a disk duplication operation using a blank disk for a disk having a slow reading response time, If the result is OK in the moved optical disc drive, the number of times of reading out the data for the previous optical disc drive is renewed, and the result of reading the data in the moved optical disc drive It is determined that the disk is a failed disk and the failed disk is moved from the cartridge 30 to the slot farthest from the drive bay 10 among the slots containing the disk (the disk on which data is recorded and the empty disk) And the disk in that slot Below it can be moved into the slot.

The controller 60 can notify the administrator or operator of the occurrence of the failed disk through the mail, text, GUI, etc., using the network unit 70 or the monitor when the disk failure occurs.

Therefore, the operator can confirm the position of the failed disk by checking only the number of failed disks included in the cartridge, and easily extract the failed disk from the cartridge without performing any additional operation.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. Addition or the like.

10: Drive bay 20: Picker robot
30: Cartridge 40: Robot transfer part
50: Fan module 60:
70: Network part 100: Archiving system

Claims (7)

In an optical disc-based archive system for transferring an optical disc between a cartridge for storing a plurality of optical discs and an optical disc drive and for writing data to or reading data from the optical disc through the optical disc drive,
Confirming whether or not the disk has failed in the optical disk drive; And
Moving the failed disk identified as failed from the cartridge to a slot farthest from the optical disk drive among the slots containing disks other than the failed disk. The method according to claim 1,
When data is written from a blank disc held in a slot closest to the optical disc drive among the slots containing empty discs in the cartridge and the disc is moved to the original slot, Wherein the failure disk is moved from a slot containing a blank disc to a slot farthest from the optical disc drive in the cartridge. 3. The method of claim 2,
Loading a blank disc in the slot where the failed disc is moved into the optical disc drive, writing the data to be written to the failed disc to the loaded disc, moving the disc to the original slot of the failed disc The method comprising the steps of: (a) providing a failed disk in an optical disk based archive system; The method of claim 3,
Further comprising updating information on a slot in which the failed disk has moved in the cartridge flash and an original slot of the failed disk in the optical disk based flash archive system. The method according to claim 1,
When the failed disk occurs while reading the recorded data after loading the disk on which the data has been already written, the failed disk is read from the optical disk drive And moving the disk in the first slot to the original slot of the failed disk. ≪ Desc / Clms Page number 20 > The method according to claim 1,
Wherein the disk having the slow read response time or the disk failed in the data read test is identified as the failed disk. The method according to claim 1,
Wherein when the disk is identified as a failed disk, the failed disk is moved to another optical disk drive to check again whether the disk has failed or not.

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