KR100932094B1 - Solid State Disk with Multiple Emulation - Google Patents

Abstract

A solid state disk having a multi-emulation function of the present invention includes a flash memory unit divided into a first area and a second area, an input / output between the first area and the second area of the flash memory unit, and a host to perform the multi-emulation function. A logic controller configured to independently process data, a central controller configured to process data by converting a logical address of a host into a physical address to process data in a flash memory unit of a first region and a flash memory unit of a second region; A host interface for performing an interface between the flash memory unit of the first region and the flash memory unit of the second region and the host.

As described above, since the functions of a hard disk and a CD / DVD ROM can be simultaneously implemented using one solid state disk, the size of the notebook can be reduced by removing the CD / DVD ROM.

Host, register, logic section, central control section, flash memory

Description

SOLID STATE DISK WITH FUNCTION OF MULTI-EMULATION

The present invention relates to a solid state disk, and more particularly, to a solid state disk having a multi-emulation function that can simultaneously implement a hard disk, CD-ROM, DVD-ROM, etc. using one solid state disk .

Recently, a solid state disk (Solid State Disk) method has been proposed as a technology capable of solving performance degradation due to a bottleneck during data input / output in a data processing device such as a computer or a notebook computer.

Solid State Disk is a flash memory based data storage device that removes motors and mechanical drives, which are indispensable for conventional hard disk drives (HDDs), and generates little heat and noise during operation. In addition, it is widely used as a next-generation storage device to replace the existing hard disk because it is not only resistant to external shocks but also shows a performance improvement of several tens of times compared to a conventional hard disk.

One or more solid state disks may be mounted in a desktop computer, for example, two, one solid state disk may be used as a program hard disk, and the other solid state disk may be used as a storage hard disk. There is an effect to increase the management efficiency.

However, in a small data processing device such as a notebook, the internal space is very narrow, and thus, a plurality of solid state disks cannot be mounted, which causes a problem of inefficient data management.

In addition, in recent years, the size and weight of notebooks have been miniaturized, but additional devices such as CD / DVD ROMs have been added in addition to data storage devices, causing a limitation in reducing the size of notebooks.

In order to solve the above problems, the present invention provides a solid state disk having a multi-emulation function for improving the management efficiency of data by implementing a hard disk, CD-ROM, DVD-ROM, etc. using one solid state disk It is for that purpose.

In addition, the present invention has a multi-emulation function that can reduce the size of the notebook by removing the CD / DVD ROM mounted on the notebook by simultaneously implementing the function of the hard disk and CD / DVD ROM using a single solid state disk It is an object to provide a solid state disk.

In order to achieve the above object, a solid state disk having a multi-emulation function of the present invention comprises a flash memory portion divided into a first region and a second region, a first region of the flash memory portion, A logic unit which independently performs input / output data processing between the second region and the host, and controls the logic unit to convert a logical address of the host into a physical address, thereby allowing the flash memory unit of the first region and the flash memory unit of the second region to A central control unit for processing data, and a host interface for performing an interface between the flash memory unit of the first region and the flash memory unit of the second region and the host.

The logic unit may include a first I / O register for processing input / output data of a flash memory unit of a first region and a second I / O register for processing input / output data of a flash memory unit of a second region.

The central control unit may include a first FTL algorithm for mapping input / output data having a logical address to data having a physical address in a flash memory unit of a first area according to a data processing command received from a first I / O register; And a second FTL algorithm for mapping input / output data having a logical address to data having a physical address in a flash memory unit of a second area according to a data processing command received from an I / O register.

The flash memory unit of the first region may be a hard disk region, and the flash memory unit of the second region may be a CD-ROM or DVD-ROM region.

The flash memory unit of the first region may be interfaced with the host by the ATA protocol, and the flash memory unit of the second region may be interfaced with the host by the ATAPI protocol.

The flash memory unit of the first region and the flash memory unit of the second region may be a hard disk region.

The flash memory unit of the first region and the flash memory unit of the second region may be interfaced with a host by the ATA protocol.

The central control unit may further include a user interface.

According to the present invention, by implementing a single solid state disk to enable multiple emulations, there is an effect of increasing data management efficiency.

In addition, the present invention can implement the functions of a hard disk and a CD / DVD ROM at the same time using a single solid state disk has the effect of reducing the size of the notebook by removing the CD / DVD ROM.

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

1 is a block diagram showing a solid state disk having a multi-emulation function according to the present invention, Figures 2 and 3 is a block diagram showing a process of implementing a solid state disk with a multi-emulation function according to the present invention.

Referring to FIG. 1, a flash memory unit 100 divided into a first region and a second region, a first region, a second region, and a host 700 of the flash memory unit 100 to perform a multi-emulation function. The logic unit 200 and the logic unit 200 is processed independently of each other, and control the logic unit 200 to map the input and output data having a logical address from the host 700 to the input and output data having a physical address The central control unit 300 processing data of the flash memory unit 110 of the first region and the flash memory unit 120 of the second region, the flash memory unit 110 of the first region, and the flash memory of the second region. And a host interface 600 that performs an interface between the unit 120 and the host 700.

The flash memory is a nonvolatile memory device that stores data, and a plurality of flash memories form a single flash memory unit 100. Here, the flash memory unit 100 may be composed of, for example, 16 flash memories (# 0 to # 15), 10 of which are the flash memory unit 110 of the first region, and the remaining six are the second. It can be achieved by the flash memory unit 120 of the region. The flash memory unit 110 of the first region may be implemented as a hard disk, and the flash memory unit 120 of the second region may be implemented as a CD-ROM or a DVD-ROM. In addition, the flash memory unit 110 of the first region and the flash memory unit 120 of the second region may be simultaneously implemented as a hard disk.

In addition, the flash memory unit 110 of the first region may be used as a master, and the flash memory unit 120 of the second region may be used as a slave. Of course, the flash memory unit 110 of the first region may be used as a slave, and the flash memory unit 120 of the second region may be used as a master. To this end, a solid stake disk is provided with a jumper (not shown). By operating the jumper, the flash memory unit 100 divided into two areas can be used as a master and a slave hard disk, respectively. The hard disk can also be used as a CD / DVD ROM.

As described above, a detailed process in which the flash memory unit 100 is divided into the flash memory unit 110 of the first region and the flash memory unit 120 of the second region and operated independently of each other will be described in detail later with reference to the accompanying drawings. Let's do it.

The logic unit 200 stores I / O for storing a data processing command received and transmitted to the host 700 for data processing of the flash memory unit 110 of the first region and the flash memory unit 120 of the second region. O registers 210 and 220 may be provided and include a first I / O register 210 and a second I / O register 220. Here, the I / O registers 210 and 220 are storage locations of data processing instructions used by the host 700 mentioned in the ATA / ATAPI protocol for data processing purposes.

The first I / O register 210 stores data processing instructions of the flash memory unit 110 of the first region, and the second I / O register 220 stores data of the flash memory unit 120 of the second region. This will save the processing instruction. As a result, the flash memory unit 110 of the first region and the flash memory unit 120 of the second region may perform different data processing commands. As a result, the flash memory unit 110 of the first region and the flash memory unit 120 of the second region may be separately configured to operate independently.

For example, when the flash memory unit 110 of the first region is used as a hard disk, and the flash memory 120 of the second region is used as a CD-ROM or a DVD-ROM, the flash memory unit of the first region implemented as a hard disk ( 110) and the flash memory unit 120 of the second region, which is implemented as a CD-ROM or a DVD-ROM, cannot store and execute a data processing instruction by one I / O register. The logic unit 200 includes a first I / O register 210 and a second I / O register 220.

Of course, in the first I / O register 210 and the second I / O register 220, the flash memory unit 110 of the first region is used as a hard disk, and the flash memory unit 120 of the second region is also hard. Of course, it can also be applied to use as a disk.

As described above, the flash memory unit 110 of the first area is used as a hard disk by storing and performing a data processing instruction by the first I / O register 210 and the second I / O register 220. When the flash memory unit 120 of the second region is used as a CD-ROM or DVD ROM, data must be processed separately, so that the flash memory unit 110 of the first region and the flash memory unit 120 of the second region are physically separated. To this end, the microcontroller unit (MCU) includes dual FTL (Flash Translation Layer) algorithms 310 and 320 which are firmware for implementing a logic-physical block mapping algorithm.

In more detail, the FTL algorithms 310 and 320 interpret a physical address of the flash memory unit 110 of the first region and physically map the corresponding data to the flash memory unit 110 of the first region. A first FTL algorithm 310 and a second FTL algorithm 320 for physically mapping the corresponding data to the flash memory unit 120 of the second region. For example, the first FTL algorithm 310 is an algorithm for physically mapping to the flash memory unit 110 of the first area used as a hard disk, and the second FTL algorithm 320 is used as a CD / DVD ROM. This is an algorithm for physically mapping to the flash memory unit 120 in two regions. The detailed algorithm for this is omitted.

Accordingly, the central controller 300 may include a first region in which input / output data is mapped to a physical region by data processing commands of the first I / O register 210 and the second I / O register 210 of the logic unit 200. The READ and WRITE may be independently performed on the flash memory unit 110 and the flash memory unit 120 of the second region. In addition, in order to store and output the input / output data in the first flash memory unit 110 and the second flash memory unit 120, the central control unit 300 and the logic unit 200 have a ROM in which programs necessary for storage and output are stored. ROM 400 and RAM 500 may be provided as a temporary storage buffer of data.

Meanwhile, a user interface 800 may be further connected to the central control unit 300, and the user interface 800 may be an additional function for a special purpose such as a boot function or a security function. It can play a role of adding. As a result, the user can utilize various functions.

The host interface 600 is directly connected to the external host 700 via a bus, and serves to interface signals such as control signals, addresses, and data between the host 700 and the solid state disk.

The host interface 600 may interface with the host 700 through the ATA protocol 610 or the ATAPI protocol 620, and typically only two devices may be connected to one bus. Here, the ATA protocol 610 is a protocol for connecting the flash memory unit 100 to the host 700 and the hard disk function, the ATAPI protocol 620 is a storage device other than the hard disk, for example, CD ROM, DVD It is a protocol for connecting with the flash memory unit 100 having a ROM function.

Accordingly, in the present invention, when the flash memory unit 110 of the first region is used as a hard disk, the flash memory unit 110 of the first region interfaces with the host 700 by the ATA protocol 610. When the flash memory unit 120 in the two areas is used as a CD-ROM or a DVD-ROM, the flash memory unit 120 in the second area interfaces with the host 700 by the ATAPI protocol 620. In addition, when both the flash memory unit 110 of the first region and the flash memory unit 120 of the second region are used as hard disks, the flash memory unit 110 of the first region and the flash memory unit of the second region ( 120 may be interfaced with each other by the host 700 and the ATA protocol 610.

Hereinafter, a process in which the flash memory unit 110 of the first region is used as a hard disk and the flash memory unit 120 of the second region is used as a CD ROM or a DVD ROM will be described with reference to FIG. 2.

As shown in FIG. 2, first, the host 700 may host a host 700 in order to inform in which area of the flash memory unit 210 of the first region or the flash memory unit 220 of the second region to store data to be transmitted. The ID is transmitted to each of the I / O registers 210 and 220 through the interface 600. If the transmitted IDs match, it may be determined that the flash memory unit of the corresponding area is selected.

When the central controller 300 determines that the host 700 processes data of the flash memory 110 of the first region from the unique ID, the central controller 300 receives the first I / O register 210 by the ATA protocol 610. According to the data processing command, the flash memory unit 110 of the first area processes data through physical mapping by the first FTL algorithm 310.

In addition, when it is determined that the data of the flash memory 120 of the second area is processed from the unique ID, the second area of the second area according to the data processing command received by the ATAPI protocol 620 to the second I / O register 220. The flash memory unit 120 processes data through physical mapping by the second FTL algorithm 310. As a result, the flash memory unit 120 of the second region can be used as a CD / DVD ROM.

As described above, according to the present invention, since a hard disk and a CD / DVD ROM function are simultaneously implemented as one solid state disk, one solid stake disk can use two independent functions as a device.

When both the flash memory unit 110 of the first region and the flash memory unit 120 of the second region are used as a hard disk, as described above, first, the flash memory unit 110 and the second region of the first region are first described. The flash memory unit 120 determines an area in which data is processed from the unique ID transmitted from the host.

When the data processing region is determined from the unique ID, the flash memory units 110 and 120 of the first and second regions are configured by the host 700 and the ATA protocol 610 according to the regions of the flash memory unit 100 to be performed. Interface. Then, through physical mapping by the first FTL algorithm 310 or the second FTL algorithm 320 according to the data processing instruction received in the first I / O register 210 or the second I / O register 220. The data of the flash memory unit 110 of the first region or the flash memory unit 120 of the second region is processed. In general, the flash memory unit 110 of the first region may be used as a hard disk for mounting a program, and the flash memory unit 120 of the second region may be used as a hard disk for data storage.

As described above, according to the present invention, one solid state disk may be used as two hard disks, and various types of storage devices may be implemented.

As described above, the solid state disk according to the present invention may implement one solid state disk as two hard disks as needed, and one hard disk and one CD / DVD ROM. Therefore, the solid state disk according to the present invention has the effect of increasing the data management efficiency.

In addition, the present invention has the effect of reducing the size of the notebook because one solid state disk can implement the functions of a hard disk and a CD / DVD ROM at the same time.

Although described above with reference to the drawings and embodiments, those skilled in the art that the present invention can be variously modified and changed within the scope without departing from the spirit of the invention described in the claims below I can understand.

1 is a block diagram showing a solid state disk having a multi-emulation function according to the present invention.

2 and 3 are block diagrams showing a process of implementing a solid state disk having a multi-emulation function according to the present invention.

<Description of the code | symbol about the principal part of drawings>

110: first flash memory unit 120: second flash memory unit

200: logic unit 300: central control unit

400: Rom 500: Ram

600: host interface 700: host

Claims (8)

A flash memory unit 100 divided into a first area and a second area to perform a multi-emulation function; A logic unit 200 in which input / output data processing between the first and second regions of the flash memory unit 100 and the host 700 is independently performed; The central control unit controls the logic unit 200 to convert the logical address of the host 700 into a physical address to process data in the flash memory unit 110 of the first region and the flash memory unit 120 of the second region. 300; And And a host interface (600) for performing an interface between the flash memory unit (110) of the first region and the flash memory unit (120) of the second region and the host (700). Having a solid state disk. The method according to claim 1, The logic unit 200 processes the first I / O register 210 for processing the input / output data of the flash memory unit 110 of the first region and the input / output data of the flash memory unit 120 of the second region. And a second I / O register (220) for the purpose of claim 1, wherein the solid state disk has multiple emulation functions. The method according to claim 2, The central control unit 300 maps input / output data having a logical address to data having a physical address in the flash memory unit 110 of the first area according to a data processing command received from the first I / O register 210. Data having a physical address in the flash memory unit 120 of the second region in the input / output data having a logical address according to the first FTL algorithm 310 and the data processing command received from the second I / O register 220. And a second FTL algorithm (320) for mapping to the multi-emulation function. The method according to any one of claims 1 to 3, The flash memory unit 110 of the first region is a hard disk region, and the flash memory unit 120 of the second region is a CD-ROM or DVD-ROM region. The method according to claim 4, The flash memory unit 110 of the first region is interfaced with the host 700 by the ATA protocol 610, and the flash memory unit 120 of the second region is connected to the host 700 by the ATAPI protocol 620. And a solid state disk having multiple emulation functions. The method according to any one of claims 1 to 3, And a flash memory unit (110) of the first region and a flash memory unit (120) of the second region are hard disk regions. The method according to claim 6, And a flash memory unit (110) of the first region and a flash memory unit (120) of the second region having a multiple emulation function interfaced with the host (700) by the ATA protocol (610). The method according to claim 1, The central control unit 300 is a solid state disk having a multiple emulation function, characterized in that further provided with a user interface (800).

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