KR20060084121A - Hard disk drive with position-changed spare cylinder including reassign sector - Google Patents

Abstract

The present invention discloses a hard disk drive device that includes a spare cylinder in a changed position that includes a redirected sector.

According to the present invention, in a hard disk drive for managing data not to appear in the data recording portion, the area is altered, the hard disk drive is located inside the hard disk, the data is recorded and stored, divided into a plurality of areas to manage the data The media, areas of the media being redirected to be accessed instead of the defect sector when a defect occurs in a plurality of normal cylinders and sectors comprising tracks comprising sectors in which normal data is recorded; It includes a spare cylinder for defect-free containing spare sectors, which is located in the middle of the first and last cylinders of the normal cylinders, which can be generated on the recording media inside the hard disk drive unit. Can occur when accessing alternate sectors to handle defects. It can further reduce the delay time and, as a result, the performance of hard disk drives as well, and makes it possible to improve the performance of a computer system equipped with the hard disk drive.

Description

Hard disk drive with position-changed spare cylinder including reassign sector}

1 is a diagram for explaining the problem of the conventional defect-free as described above.

2 is a diagram for describing a defect free method.

Figure 3 shows an example in which the position of the spare cylinder is adjusted in accordance with the present invention.

Figure 4 shows the location of two spare cylinders in one area according to the invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording and storage device, wherein a redefined sector capable of minimizing delay time while performing defect-free so that a damaged area is not displayed in a recording and storage device such as a hard disk drive is not displayed. It relates to a hard disk drive device including a spare cylinder of the changed position to include.

In the case of a hard disk drive (hereinafter referred to as an HDD), a defect may be generated on the surface of a medium on which data is recorded, even if data is not recorded or recorded for some reason. Since such defect part is a direct cause of the error from the user's point of view, such defect should not be exposed to the user if possible. As such, even if there is a defect in the HDD, the defect is not exposed to the user so that the user does not interfere with the defect.

Devices that record and store data, such as HDDs, are pre-defected during the drive manufacturing process in order to enable end users to use the device free of defects in the recording area. scan) to execute the defect management procedure to process the defect portion.

There may be a number of defect free methods. Some examples are:

If an defect is found in an area during inspection during the manufacturing process, the addresses are slipped one by one from the sector immediately after the defect to the spare cylinder at the end of the area so that the defect is not accessed.

Alternatively, when a new defect is additionally found in the general user's use environment, the spare area is referred to instead of the corresponding sector where the defect is generated so that the defect area is not accessed.

In such a case, there may be a problem of time delay in accessing an area instead of a defect. 1 is a view for explaining the problem of the conventional defect-free in this way.

If a defect is found in the media 100 of the HDD, the sector to replace the sector where the defect has occurred is replaced with a sector included in the last two cylinders of the region. In other words, if the defect occurs, the user will receive an error even if the defect occurs by reading (or writing) the sector replaced by the sector (or writing) instead of reading (or writing) the sector where the defect occurred. Do not do it.

In this process, there is no big problem in the case where the defect occurs in the part located close to the cylinder containing the replacement sector, but if the defect occurs in the sector included in the first cylinder of the zone, The delay time due to the seek time of the HDD may increase. Increasing the delay time when reading or writing data is a major factor that degrades the performance of HDDs for storing and retrieving large amounts of data.

For example, assume that a defect occurs in the first cylinder in the region of FIG. 1 and the defect sector is moved to a replacement sector in the last cylinder that is 1000 cylinders away from the portion. If a defect sector is included in the reading of consecutive data, the head of the HDD reading the data moves 1000 cylinders from the point where the defect occurred to the replacement sector to read the data recorded in the replacement sector, and then the defect is reset. You have to move 1000 cylinders back to the next sector that occurred.

It can be seen that a lot of delay time is generated in this process. If multiple defects occur in one area, the delay can be extended to a greater degree, resulting in performance degradation of systems such as computer systems using HDDs.

The technical problem to be solved by the present invention is to solve the above problems, even if the defect occurs in the recording and storage device, such as a hard disk drive, even if the defect-free processing is not exposed to the user due to this performance An object of the present invention is to provide a hard disk drive device including a spare cylinder of a changed position including a redirected sector which can minimize the problem of degradation.

According to the present invention for solving the above technical problem, the hard disk drive device including a spare cylinder of the changed position including the redesignated sector, the hard disk drive for managing so that the area in which data is altered in the data recording portion is not expressed In the hard disk, the data is recorded and stored, and divided into a plurality of areas includes a media that is managed data, the area of the media, includes a sector that is a unit in which normal data is recorded A plurality of normal cylinders comprising tracks; And a spare cylinder for a defect free including spare sectors that are redirected to be accessed instead of the defect sector when a defect occurs in the sectors, wherein the spare cylinder is the first of the normal cylinders. It is located in the middle region of the cylinder and the last cylinder.

At this time, the intermediate region in which the spare cylinder is located preferably has a position value closest to the average of the position value of the first cylinder and the position value of the last cylinder.

In addition, the spare cylinder is two, the first spare cylinder has a position value closest to the average of the position value of the first cylinder and the position value of the last cylinder, the second spare cylinder of the position value of the last normal cylinder It is desirable to have the following position values.

And at this time, the spare sector for the defect generated in the region located between the normal cylinder having the first position value and the first spare cylinder is included in the first spare cylinder, the area after the first spare cylinder From the second spare cylinder is preferably included in the spare sector for the defect occurring in the region before the second spare cylinder.

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

First, the defect free method will be described.

1.Slip Sector

This technique is used in the process to find defects scattered across the media surface, slipping addresses by one address from the sector immediately behind the defect to the spare cylinder at the end of each zone. Do not access it.

2 is a diagram for describing a defect free method.

The state of I shows that a defect has occurred. Defect has occurred in the sector at address D2 of the reference number 200. In this state, the result of the defect free as described above is the state of II.

The defect that occurred in I is marked as 200-1 in II. The sector where this defect occurred is left blank, and the address of the sector which was addressed as D3 in the previous I state is changed to address D2 and below. Sectors likewise change their address. As a result, the sectors after the defective sector are the same as pushing the addresses back one by one. The last sector in the state of I is addressed to D799 in the II state, and one more sector 210 is added to address to D800. This defect-free case does not require additional navigation or additional rotation of the media to access the replacement area. In this case, the sector 210 is also referred to as a virtual sector.

2. auto reassign

In the HDD manufacturing process, additional defects may be found while using in the environment used by the user. In this case, the defect may be referred to by referring to the spare area prepared in advance instead of the corresponding sector where the defect is found. Do not access it. There are two ways depending on where you want to set the spare area:

1) Spare Cylinder / Zone

The entire media that records data inside HDD is divided into several zones. The last two cylinders of each zone are set as spare cylinders. In this case, the delay due to the search time may increase according to the distance from the original sector to the replacement sector.

2) Spare Sector / Cylinder

Set two sectors as spare sectors on every track. No seek time is needed to access the spare cylinder, but three media rotations are needed to access the sector at the end of the track.

3. Partial description of the method used in the present invention

When the re-designation occurs as described above, the sector is slipped. The result is the state of III of FIG. The result is similar to the slipped result of II. However, the last sector of the track is reassigned to the spare cylinder in consideration of skew to minimize the access time to the reassignment sector.

The present invention uses such a method. At this time, the delay due to the revolution or rotation of the media is minimized, but there is a delay due to the seek time as the skew is applied. To further reduce this, the present invention further refines such a configuration.

The search time it takes to find a sector that is replaced in the defect sector is proportional to the distance between the cylinders containing the sector. In the worst case, when a defect occurs in the first cylinder of a certain area, it must search the distance corresponding to the entire cylinder in the area to find the spare cylinder at the end of the area.

In the present invention, the spare cylinder is located in the center of the region in order to minimize the search time.

Figure 3 shows an example in which the position of the spare cylinder is adjusted in accordance with the present invention.

The media is divided into several regions, and as shown in FIG. 1, one region is displayed to be distinguished from another region.

One area of this media contains a plurality of normal cylinders containing tracks comprising sectors in which normal data is recorded. 3 shows an example including 1000 normal cylinders in one region.

When a defect occurs in the sectors included in the area, a spare cylinder for defect-free containing extra sectors which are redirected to be accessed instead of the defect sector is also displayed. The spare cylinder is then located in the middle of the first and last cylinders of the normal cylinders.

More specifically, the intermediate region in which the spare cylinder is located has a position value closest to the average of the position value of the first cylinder and the position value of the last cylinder. In the example of FIG. 3, an extra cylinder is relocated at a position of 500 or 501 which is the value closest to the average of the position value 1 of the first cylinder and the position value 1000 of the last cylinder.

When the HDD executes a search operation, the HDD always checks whether there is a defect in the track by referring to a slip list in which information on defects created in the manufacturing process is written. The sleep list is loaded and stored in the same means as RAM embedded in the HDD.Then, the loaded sleep list is modified with reference to the loaded redirection list so that the defect sector is read and written like a defect-free sector. It no longer accesses and goes to the reassigned replacement sector.

In the conventional case, for example, if the number of cylinders per region is 1000, defects occur as shown in FIG. 1, and redesignation is performed. Then, a delay of 1000 sector search time occurs to access the corresponding sector.

However, the spare cylinder to be loaded as shown in Figure 3 is located in the center cylinder of the area. This reduces the seek time by one-half compared to the 500-cylinder, i.

However, in the case of FIG. 3, if there is a defect past the part where the spare cylinder is located while continuously reading data recorded in tracks or sectors located before and after the relocated spare cylinder, the header for reading the data is in a forward direction for reading. You have to reverse the direction, come to the spare cylinder, read the data you need, go back in the original direction, and read the contents of the next sector. If such a case is repeated, an excessive force may occur due to the change in the direction of travel of the header.

Figure 4 shows the location of two spare cylinders in one area according to the invention. The first spare cylinder is positioned as in the case of FIG. 3, and the second spare cylinder is placed at the last cylinder position of the region. The second spare cylinder is the cylinder position next to the last normal cylinder in the area, relative to the normal cylinder.

In addition, the spare sectors for defects occurring in the area between the normal cylinder with the first position value and the first spare cylinder are included in the first spare cylinder, and the second from the area after the first spare cylinder. The extra sector for defects occurring in the area before the spare cylinder can be included in the second spare cylinder to further minimize head movement.

Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. Examples included in the above description are introduced for the understanding of the present invention, and these examples do not limit the spirit and scope of the present invention. It will be apparent to those skilled in the art that various embodiments in accordance with the present invention in addition to the above examples are possible. The scope of the present invention is shown not in the above description but in the claims, and all differences within the scope will be construed as being included in the present invention.

According to the present invention, in a hard disk drive for managing data not to appear in the data recording portion, the area is altered, the hard disk drive is located inside the hard disk, the data is recorded and stored, divided into a plurality of areas to manage the data The media, areas of the media being redirected to be accessed instead of the defect sector when a defect occurs in a plurality of normal cylinders and sectors comprising tracks comprising sectors in which normal data is recorded; It includes a spare cylinder for defect-free containing spare sectors, which is located in the middle of the first cylinder and the last cylinder of the normal cylinders, and can be generated on the recording media inside the hard disk drive unit. Can occur when accessing an alternate sector to handle an existing defect. It can further reduce the delay time and, as a result, the performance of hard disk drives as well, and makes it possible to improve the performance of a computer system equipped with the hard disk drive.

Claims (4)

In a hard disk drive that manages to prevent an area in which data is altered in a data recording portion, Located in the hard disk, the data is recorded and stored, and comprises a media divided into a plurality of areas where the data is managed, Areas of the media, A plurality of normal cylinders including tracks comprising sectors in which normal data is recorded; And And a spare cylinder for defect-free that includes spare sectors that are redirected to be accessed instead of the defect sector when a defect occurs in the sectors. And said spare cylinder is located in an intermediate region between a first cylinder and a last cylinder of said normal cylinders. The method of claim 1, An intermediate region in which the spare cylinder is located has a position value closest to the average of the position value of the first cylinder and the position value of the last cylinder; Drive unit. The method according to claim 1 or 2, The spare cylinder is two, The first spare cylinder has a position value closest to the average of the position value of the first cylinder and the position value of the last cylinder, And a second spare cylinder has a position value following a position value of the last normal cylinder. The method of claim 3, The spare sector for the defect occurring in the region located between the first cylinder and the normal cylinder having the first position value is included in the first spare cylinder. The spare sector for defects occurring in the area after the first spare cylinder and before the second spare cylinder is included in the second spare cylinder. Hard disk drive unit containing spare cylinders.

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