KR100928037B1 - Semiconductor storage media disks with dynamic expansion and contraction of storage capacity and file system - Google Patents

Abstract

The present invention relates to a semiconductor storage medium disk, comprising: a hard disk controller unit connected to a data bus and supporting protocols of ATA, SATA1, SATA2, and SAS methods; A flash memory controller connected to the hard disk controller to support reading and writing data of a flash memory; A flash memory unit connected to the flash memory controller to store data; And a slot-type interface unit configured to allow a memory module to be mounted and connected to the flash memory unit, wherein the hard disk controller unit is preset to a maximum memory loading state in which all of a predetermined number of memory modules are mounted. By reconfiguring the usable memory capacity by attaching and detaching the memory module to the interface unit, it can be used as a storage device with excellent data safety due to the strong durability against physical shock, and according to the characteristic of high processing speed Eliminate bottlenecks to improve computing performance, increase and decrease data storage capacity in real time, and dynamically scale up and down without recreating the file system to maximize storage utilization. Can be.

Flash memory, hard disk, SSD

Description

Flash solid state disks for dynamically expanding and shrinking storage capacity and file systems

1 is a block diagram of a conventional storage medium disk;

2 is a configuration diagram of a semiconductor storage medium disk (SSD) to which the present invention is applied;

3 is a configuration diagram of a file system when mounting and detaching a memory module according to the present invention.

* Explanation of symbols for main parts of the drawings

110: computer 120: control and memory module

125: hard disk controller 121a, 121b, 121c, 121d: memory controller

122a, 122b, 122c, 122d: first to fourth status information registers

123a, 123b, 123c, 123d: flash memory

The present invention relates to a semiconductor storage medium disk (Solid State Disk, hereinafter referred to as SSD) and a method of manufacturing the same, and more particularly to a flash memory expansion module for expanding the storage capacity of the SSD.

Generally, data throughput, which is a performance indicator of a computer, depends on the speed of a storage device. Since most operating systems (OSs) require multiprocessing, a hard drive disk is required. The input / output (I / O) bottleneck of I / O is intensifying.

Conventional SSDs are used in the same way as conventional hard disks with disc disks by storing data using memory controllers and flash memory modules that are connected to the data I / O bus and support ATA, SATA1, SATA2, and SAS protocols. Can be.

      Existing hard disks are extremely inferior in stability due to the presence of physical operation parts, but SSDs have relatively superior stability compared to hard disks by using semiconductors as storage media.

      Conventional hard disks have a problem of slow data processing due to the disk's seek time that combines the time it takes for the head to move to a specific track of the disk and the rotational latency, but the SSD seeks near zero. This can lead to faster processing speeds.

     Hard disks have a relatively long life due to physical operation, whereas SSDs have a relatively long life.

      However, SSDs, which have a lot of advantages, are nearing the price of hard disk due to the improvement of semiconductor manufacturing technology, but remain expensive. In order to replace hard disks, SSDs have become the biggest barrier.

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1 is a block diagram of a conventional memory storage device, in which a plurality of memory controllers 30a and 30b for controlling flash memories 40a and 40b attached to a hard disk controller are connected to a hard disk controller 20 so that a flash memory hard disk may be connected. It works as

The conventional SSD configured as described above can not be used to expand the memory because the expensive memory can be used only with a fixed capacity, and the file system after backing up the existing data when the capacity is expanded by using a plurality of parallel SSDs of the same type This requires a lot of time and money because the original data must be copied again after the deletion and rewrite.
That is, in the conventional semiconductor storage medium disk, it is difficult to expand the flash memory itself because no hardware and software processing capable of expanding the flash memory is involved. In addition, even if it is possible to expand by parallel connection, it was difficult to rebalance the storage capacity of the expanded SSD hard disk controller, it was inconvenient to delete the existing data and then resave.

In order to solve the above problems, the present invention utilizes SSD semiconductor memory to increase and decrease memory capacity in real time, and accordingly, a semiconductor storage capable of dynamically expanding and contracting a storage capacity and a file system while maintaining an existing file system. It is an object to provide a media disk.

In order to achieve the above object, the present invention provides a semiconductor storage medium disk capable of increasing or decreasing semiconductor memory storage capacity, comprising: a hard disk controller unit connected to a data bus and supporting ATA, SATA1, SATA2, and SAS protocols; ; A flash memory controller connected to the hard disk controller to support reading and writing data of a flash memory; A flash memory unit connected to the flash memory controller to store data; And a slot-type interface unit configured to allow a memory module to be mounted and connected to the flash memory unit, wherein the hard disk controller unit is preset to a maximum memory loading state in which all of a predetermined number of memory modules are mounted. The memory module may be reconfigured from the memory module to the interface unit by receiving state information including the memory use state of the memory module from the memory module.

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

2 is a configuration diagram of a semiconductor storage medium disk (SSD) to which the present invention is applied, the hard disk controller 125 connected to a data input / output bus and supporting the ATA / SATA1 / SATA2 / SAS protocol, and the hard disk controller unit ( 125 is connected to the flash memory controller 121a, 121b, 121c, 121d and the flash memory controller 121a, 121b, 121c, 121d to control data read / write of the flash memory. Interface unit (not shown) for connecting additional memory to the flash memory unit 123a, 123b, 123c, 123d and the status information register 122a, 122b, 122c, 122d having state information of the memory module and the flash memory unit. City). That is, in FIG. 2, each memory module connected to each other by a solid line means that the memory modules may be electrically connected to each other through an interface unit.
Here, the interface unit may be formed in various forms. In the present invention, the interface unit is illustrated as being configured in a slot form. However, since the slot-type interface configuration is well known to those skilled in the art, a detailed description of the configuration is omitted in the present invention.

The detailed configuration of the semiconductor storage medium disk (SSD) configured as described above is as follows.

First, the hard disk controller 125 is set to a maximum memory loading state in which all N memory modules are mounted, and is set to use only the actual capacity when the first one module is mounted. As shown in FIG. 3, each memory module has a storage capacity of 16G, and up to four memory modules may be mounted including one memory module in an initial installed state, and one memory module may be installed in an initial hard disk controller. If it is connected, the hard disk controller unit is set to 64G in which all four memory modules are loaded. However, since only one memory module is actually used, only 16G corresponding to the first partition can be used.
In this state, if the module 1 is mounted on the interface unit (not shown), the hard disk controller unit is readjusted to use the second partition in the partition data.

As described above, the storage capacity of the hard disk controller unit is readjusted by the state information 122a-d, 132a-d, 142a of the memory module added by connecting the hard disk controller unit 125 and the memory modules 130, 140, and 150 to each other. -d, 152a-d) is delivered by the hard disk controller unit 125 to automatically readjust the available storage capacity, and by adjusting the file system to be expanded accordingly using dedicated software.

3 is a diagram illustrating a file system configuration when a memory module is mounted and detached according to an embodiment of the present invention, wherein a hard disk controller 125 connected to a data input / output bus and a flash memory performing a function of designating an actual total available memory capacity are illustrated in FIG. The memory unit 123, 130, 140, 150 capable of storing data under the control of the controller 121, the flash memory controller 121, and the file system may be reduced and expanded based on information of the memory controller 125. It is made up of dedicated software.

Looking at the processing flow according to the configuration as described above are as follows.

First, after setting the maximum memory loading state in which all the memory modules are mounted, adjust the partition information of the hard disk controller unit 125 so as to use only the actual capacity when one module is mounted, and then additionally install the module. Whenever the hard disk controller unit 125 receives status information from each module, it is designed to automatically increase the actual capacity of the hard disk controller unit 125 and accordingly to expand the file system without destroying the dedicated software. Adjust through

In this case, the operating system's file system should be set to the capacity of the first one or the first installed module, and the module can be expanded to the new capacity while maintaining the existing file system when additional modules are installed.

In addition, when removing the module, if the file system is reduced as much as the capacity of the module to be removed in advance, and the module is physically removed, the user can add and remove as many modules as necessary and the file system can be expanded and rebuilt without rewriting accordingly. Reduction is possible.

As described above, the present invention can easily expand and reduce the capacity of an expensive SSD at a time required by the user, and accordingly, it is possible to expand the SSD without having to recreate the file system.
That is, in the present invention, an additional memory module can be installed by additionally providing an interface unit capable of increasing the capacity by escaping a single module manufacturing method of the conventional SSD, so that the capacity can be easily increased from a small capacity to a large capacity. Existing SSD has to discard the existing product in order to upgrade capacity, but SSD of the present invention purchases an additional low-cost memory module after a long time after purchasing the initial low capacity SSD in response to the rapid drop in flash memory price Therefore, by expanding the capacity, it is not necessary to discard the existing module, the maximum capacity can be used at the minimum price, and a long life cycle can be obtained from product purchase to disposal.
Increasing the capacity inside the SSD affects the file system that has already been created, but the present invention enables users to easily expand and reduce the file system without destroying the existing file system despite the addition or removal of memory modules.
On the other hand, the data throughput, which is a performance indicator of a computer, depends on the speed of the storage device. Since most O / S require multi-processing, the I / O bottleneck of the HDD is intensifying. This eliminates the / O bottleneck and enables significant performance improvements.
In addition, since the SSD is highly resistant to physical shocks, the SSD can provide mobility to laptops, PCs, and the like, thereby ensuring the stability of data even when a disk is damaged and having the advantage of computing while moving.
In addition, since the flash memory SSD of the present invention has no mechanical device at all, the flash memory SSD has excellent stability and durability, and thus, the flash memory SSD may exhibit much better performance than the HDD.
Moreover, as the desire to store and speed up secure data on individual PCs is increasing these days, it is possible to modularize a dedicated memory that can increase storage and speed, expand capacity in real time, and improve memory. It can have advantages.

Claims (10)

A semiconductor storage medium disk capable of increasing or decreasing semiconductor memory storage capacity, A hard disk controller connected to a data bus and supporting protocols of ATA, SATA1, SATA2, and SAS methods; A flash memory controller connected to the hard disk controller to support reading and writing data of a flash memory; A flash memory unit connected to the flash memory controller to store data; and And a slot-type interface unit mounted on the flash memory unit to be connected to each other. The hard disk controller unit is preset to a maximum memory loading state in which a predetermined number of memory modules are all mounted, and the memory module of the memory module is used through the interface unit from the memory module by detaching the memory module from the interface unit. A semiconductor storage medium disk capable of dynamically expanding and contracting a storage capacity and a file system, characterized by readjusting a usable memory capacity by receiving status information containing states. delete delete delete delete delete delete delete delete delete

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