KR101267441B1 - Computer system having cradle and block managing method thereof - Google Patents

Abstract

The present invention relates to a block management method for synchronizing data of two computers using a computer system provided with a cradle connecting two computers, and specifically, a first computer and a second including a first auxiliary storage device. A second computer including an auxiliary memory, a connection bus and a cradle; The first auxiliary memory device includes a block management module, block management information, and a plurality of numbered access blocks, wherein the block management module utilizes the block management information for the first computer and the first computer. It relates to a method of synchronizing the blocked data, the convenience and mobility of the work using a computer is maximized, and even when the first computer is separated from the second computer, recently used data is automatically updated on the first computer. The data can be used as conveniently as when connected to a second computer, and data changed on a separate first computer is automatically updated on the second computer when connected to the second computer, so that the user can use it conveniently. In addition, the data is safer than using only conventional mobile computers. Is an effect, there is an effect that the second can be cheaper to machine and reduce costs, while storing a large amount of data by utilizing the auxiliary storage device is a large capacity because the auxiliary memory unit of the mobile computer is expensive in size than the storage capacity.

Description

Block management method using computer system with cradle {COMPUTER SYSTEM HAVING CRADLE AND BLOCK MANAGING METHOD THEREOF}

The present invention relates to a block management method for synchronizing data of two computers using a computer system provided with two computers and a cradle connecting them.

As conventional tablet PCs, netbooks, and notebooks focus on mobility, they use a low power consumption CPU and a small main memory. On the other hand, desktop PCs can be implemented with high performance at relatively low cost because they are less restricted in power consumption, weight, size, etc., but have the disadvantage of limited mobility.

In order to solve the above problems, a plurality of docking stations and the like, which can be used with improved performance by connecting a tablet PC or a notebook to the main body of the desktop, have been developed.

However, in the past, the focus was mainly on the development of the hardware part, and only the physical connection between the two computers became more convenient than before. In terms of software using data, the two PCs can be used as one PC. It wasn't. In other words, when creating or changing data using only a portable terminal such as a notebook, even if the user connects to the desktop using a docking station, the user must manually store the data on the desktop. In order to maintain the data, there was an inconvenience in that the user directly stored the data of the main body in the notebook.

The present invention is a computer system for utilizing both mobile and performance advantages of both computers by using a mobile computer such as a tablet PC or a laptop and a high performance computer. Comprising a cradle connecting the two computers, by providing a block management function having a function for automatically synchronizing the data of the two computers, to overcome the problem of data inconsistency of the two computers, which is a problem in the conventional inventions, Even if the user does not manually store the data in the desktop main body, there is provided a computer system that can use two PCs as one PC.

In order to achieve the above object, the computer system of the present invention includes a first CPU, a first main memory device, a first input / output bus, a first connector 11, a display, an input device, and a first auxiliary memory device 12. A first computer 10; A second computer 20 including a second CPU, a second main memory device, a second input / output bus, a second connector 21, and a second auxiliary memory device 22; A cradle 30 including a connection bus, a third connector 31, and a fourth connector 32; The first I / O bus is connected to the first CPU, the first main memory device, the first connector 11, the display, the input device, and the first auxiliary memory device 12 to transfer data. The second input / output bus is connected to the second CPU, the second main memory device, the second connector 21, and the second auxiliary memory device 22 to transmit data, and the connection bus is connected to the third connector 31 and the fourth. Is connected to the connector 32 to transfer data, the first auxiliary storage device 12 includes a block management module 14, block management information 15, a number of connection blocks 13, The second auxiliary memory device 22 includes a plurality of numbered reference blocks 23, and when the first computer 10 is used in connection with the second computer 20, the first computer ( 10) connect the second computer 20 with a wired or wireless network to exchange data, or connect the first connector 11 to the third connector 31. The second connector 21 is connected to the fourth connector 32 to transmit and receive data. The block management module 14 receives data of the connection block 13 and the reference block 23. When the block management information 15 is changed, the block is updated in real time. The access block 13 is divided into a storage block 13a or a free block 13b, and the storage block 13a is a block in which data is stored. The free block 13b is a block in which data is not stored, and the number of the storage block 13a and the free block 13b is variable, and the number of the storage block 13a and the free block 13b is variable. The sum of the same as the total number of the access block 13, the block management information 15 stores the storage block number, reference block number, the last access time, whether the synchronization for each storage block (13a), The storage block number is the number of the storage block 13a, and the reference block number is the Number of the reference block 23 to be synchronized to the long block 13a, and the last access time is the time of the last access to the storage block 13a, and whether or not the synchronization corresponds to the data of the storage block 13a. If it is synchronized to the reference block 23, it is characterized in that it is stored as T, F is not synchronized.

In order to achieve the above object, in the computer system and the block management method of the present invention, in a state where the first computer 10 is connected to the second computer 20, a user moves to the first computer 10. When the number of the reference block 23 to be accessed is not stored in the reference block number of the block management information 15, when there is a free block 13b among the access blocks 13, the block management module (14) converts the free block 13b into the storage block 13a by storing the data of the reference block 23 to be accessed in the free block 13b, and free of the access blocks 13; If there is no 13b, the block management module 14 stores the data of the reference block 23 to be accessed. The storage block 13a having the oldest last connection time among the storage blocks 13a whose T is synchronized or not. In the storage block 13a which stores the data of the reference block 23 to be accessed. It is characterized by updating the last connection time.

In order to achieve the above object, the computer system and the block management method of the present invention, when the user changes the data by accessing the storage block (13a) with the first computer 10, the storage block for changing the data It is characterized in that the synchronization of 13a is changed to F.

In order to achieve the above object, a computer system and a block management method of the present invention include a free block 13b of the access block 13 when a user generates and stores new data with the first computer 10. In this case, the block management module 14 stores the new data in the free block 13b, thereby converting the free block 13b into a storage block 13a, and free block of the connection block 13. If there is no (13b), the block management module 14 replaces the data of the storage block 13a with the longest last connection time among the storage blocks 13a whose synchronization status is T with the new data, and The last access time of the storage block 13a storing the new data is updated, and the synchronization is changed to F.

In order to achieve the above object, in the computer system and the block management method of the present invention, in the state where the first computer 10 is separated from the second computer 20, whether the storage block 13a is synchronized or not. When there is a change to F, when the first computer 10 is connected to the second computer 20, the block management module 14 corresponds to each reference block corresponding to the storage block 13a whose synchronization is F. Replace the data of 23 with the data of each storage block 13a whose synchronization is F, change the synchronization to T, and separate the first computer 10 from the second computer 20 If there is a newly created storage block 13a, when the first computer 10 is connected to the second computer 20, the block management module 14 causes the newly created storage block 13a. ) Is synchronized with the reference block 23 having no data, and synchronization of the newly created storage block 13a is performed. A characterized in that the change in T.

In order to achieve the above object, in the computer system and the block management method of the present invention, the user connects the first computer 10 and the second computer 20 to work, and then the first computer 10 and the second computer. When one or more of the computers 20 are terminated or the user disconnects the first computer 10 and the second computer 20 after the first computer 10 and the second computer 20 are connected to each other. The block management module 14 selects N storage blocks 13a having a predetermined number in order of the last access time of the storage blocks 13a, and references the N storage blocks 13a connected to each other. After replacing the data of the N reference blocks 23 corresponding to the number with the data of the N storage blocks 13a, respectively, the N storage blocks 13a are converted into the free blocks 13b. It is done.

In order to achieve the above object, the computer system of the present invention is characterized in that the cradle 30 includes a power supply device for supplying power to the first computer 10.

The present invention comprises a first computer which is a mobile computer, a second computer having excellent performance, and a cradle connecting the two computers, and providing a block management function having a function of automatically synchronizing data of the two computers. The convenience and mobility of the used work is maximized, and even when the first computer is separated from the second computer, recently used data is automatically updated and retained on the first computer. In addition, the data changed from the separated first computer is automatically updated to the second computer when connected to the second computer, so that the user can use it conveniently and use only a conventional mobile computer. Data is more secure, and the security of mobile computers The storage device is a cost due to a size compared to the storage effect of the second computer to be low and to reduce the amount of data while saving the cost by utilizing the auxiliary storage device is a large capacity.

1 illustrates a computer system of the present invention.
2 illustrates a first auxiliary memory device applied to the computer system of FIG.
3 illustrates a second auxiliary memory device applied to the computer system of FIG.
4 (a) is an exemplary diagram of a connection relationship between the blocks of FIGS. 2 and 3,
FIG. 4B is a diagram showing block management information of FIG. 4A; FIG.

The cradle computer system of the present invention and the block management method using the same are composed of two types of detachable computers including a computer focused on mobility and a fixed computer body focused on high specifications, and have a high speed input / output bus function. 1 is a diagram illustrating a computer system of the present invention, and FIG. 2 is a diagram of a first auxiliary memory device applied to the computer system of FIG. 1. 3 is a view showing a second auxiliary memory device applied to the computer system of FIG. 1, FIG. 4A is an exemplary diagram of a connection relationship between the blocks of FIGs. 2 and 3, and FIG. 4B. 4 is a block management information of FIG. 4A, which is described in more detail with reference to the drawings.

Computer system configuration

The computer system of the present invention includes a first CPU, a first main memory device, a first input / output bus, a first connector 11, a display, an input device, and a first auxiliary memory device 12, as shown in FIG. A first computer 10, a second CPU, a second main memory device, a second I / O bus, a second connector 21, a second auxiliary memory device 22, including a second auxiliary memory device 22, a connection bus, and a third connector 31, the cradle 30 including the fourth connector 32 is configured.

The first I / O bus is connected to the first CPU, the first main memory device, the first connector 11, the display, the input device, and the first auxiliary memory device 12 to transfer data, and the second I / O bus is connected to the first I / O bus. It is connected to the second CPU, the second main memory device, the second connector 21, the second auxiliary memory device 22 to transfer data, and the connection bus is connected to the third connector 31 and the fourth connector 32. Connect and pass data.

The first computer 10 is a computer focused on mobility and uses a mobile microprocessor as the first CPU for minimal weight and power saving, and the first auxiliary storage device 12 to increase power saving and input / output speed. SSD disk etc. can be used. That is, in the case of the first computer 10, compared to a general notebook computer, ODD drives, hard disks, etc. do not use often, and consume a lot of power and bulky devices to reduce weight and volume and save power, such peripheral devices If necessary, the first computer 10 and the second computer 20 can be used in a connected state.

When the first computer 10 is connected to the second computer 20 and used, the first computer 10 and the second computer 20 may be connected to each other via a wired or wireless network to exchange data, or the first connector may be used. (11) is connected to the third connector 31, and the second connector 21 is connected to the fourth connector 32 to exchange data.

In addition, the cradle 30 may further include a power supply device for supplying power to the first computer 10.

As shown in FIG. 2, the first auxiliary storage device 12 includes a block management module 14, block management information 15, and a plurality of numbered connection blocks 13, and the connection block 13. ) Is divided into a storage block 13a or a free block 13b, wherein the storage block 13a is a block in which data is stored, and the free block 13b is a block in which no data is stored, and the storage block 13a. ) And the number of free blocks 13b are variable, but the sum of the numbers of the storage blocks 13a and the free blocks 13b is equal to the total number of the access blocks 13. In addition, the block management module 14 changes the data of the access block 13 and the reference block 23, and updates in real time when the block management information 15 is changed. For example, as shown in FIG. 2, if the number of access blocks 13 is M and the storage blocks 13a of the access blocks 13 are L (L is 0 or more and M or less), the access block ( 13 free blocks (13b) of the number, the M is maintained by a predetermined value unless the user or installer of the computer system changes, but the L is automatically changed by the block management module 14 do.

The second auxiliary memory device 22 includes a number of reference blocks 23, numbered as in FIG.

The storage block 13a is connected to and synchronized with the reference block 23 one by one, and the meaning of being synchronized is that they store the same data. In addition, the number of reference blocks 23 is greater than the number of access blocks 13, and always equals to or greater than the number of storage blocks 13a and serves to supplement the storage capacity of the first computer 10.

The block management information 15 stores a storage block number, a reference block number, a last access time, and synchronization for every storage block 13a, as shown in FIG. 4 (b). Is the number of the block 13a, the reference block number is the number of the reference block 23 synchronized with the storage block 13a, the last access time is the time of the last access to the storage block 13a, The synchronization is stored as T when the data in the storage block 13a is synchronized with the corresponding reference block 23, and as F when it is not synchronized.

If the first storage block 13a is synchronized with the 9th reference block 23 as in the case of FIG. 4 (a), it is stored in the storage block number and the reference block number of the block management information 15 as shown in FIG. 4 (b). 1 and 9, which are the numbers of the storage block 13a and the reference block 23, are described, respectively. In the block management information 15, the last access time of the first storage block number is September 21, 2010 16:24:46, and the synchronization is T, so refer to the data of the first storage block 13a and the number 9. The data in block 23 is exactly the same.

However, the second storage block 13a is synchronized with the 31 reference block 23, but since the synchronization is F, the data of the 2nd storage block 13a cannot be synchronized after the change, and thus the 31 reference block 23 is not synchronized. You can see that we have different data from.

In addition, since the third storage block 13a does not have the synchronized reference block 23, it can be seen that newly generated data is inputted to data that was the conventional free block 13b and converted into the storage block 13a.

Block Management Method Using Computer System

(1) read block

In the state where the first computer 10 is connected to the second computer 20, the number of the reference block 23 to be accessed by the user to the first computer 10 is the number of the block management information 15. When not stored in the reference block number, when there is a free block 13b among the access blocks 13, the block management module 14 sends data of the reference block 23 to be accessed by the free block. By storing in 13b, the free block 13b is converted into a storage block 13a.

In the state where the first computer 10 is connected to the second computer 20, the number of the reference block 23 to be accessed by the user to the first computer 10 is the number of the block management information 15. When not stored in the reference block number, if there is no free block 13b among the access blocks 13, the block management module 14 synchronizes the data of the reference block 23 to be accessed. The last access time of the storage block 13a having T is stored in the oldest storage block 13a, and the last access time of the storage block 13a storing the data of the reference block 23 to be accessed is updated.

(2) block modification

When the user accesses the storage block 13a with the first computer 10 and changes the data, whether or not the storage block 13a with the changed data is synchronized is changed to F. FIG.

(3) Write block

When a user generates and stores new data with the first computer 10, when there is a free block 13b of the access block 13, the block management module 14 sends the new data to the free block. By storing in 13b, the free block 13b is converted into a storage block 13a.

When the user generates and stores new data with the first computer 10, when there is no free block 13b among the access blocks 13, the block management module 14 stores whether the synchronization is T or not. Replace the data of the storage block 13a with the oldest last connection time of the block 13a with the new data, update the last access time of the storage block 13a storing the new data, and check whether or not the synchronization is performed. Change to

(4) Synchronization

When the first computer 10 is separated from the second computer 20 and there is a change in synchronization among the storage blocks 13a to F, the first computer 10 is changed to the second computer. In connection with (20), the block management module 14 stores the data of each reference block 23 corresponding to the storage block 13a in which the synchronization is F. Each storage block 13a in which the synchronization is F. It is characterized by replacing the data with, and changing the synchronization to T.

When the first computer 10 is separated from the second computer 20 and there is a newly created storage block 13a, the first computer 10 is connected to the second computer 20. Then, the block management module 14 synchronizes the newly created storage block 13a with the reference block 23 having no data, and changes whether or not the newly created storage block 13a is synchronized to T. It features.

(5) Creation of free blocks

After the user connects and works with the first computer 10 and the second computer 20, one or more of the first computer 10 and the second computer 20 are terminated, or the user ends the first computer ( When the first computer 10 and the second computer 20 are separated after the 10 computer and the second computer 20 are connected to each other, the block management module 14 is the last of the storage blocks 13a. N storage blocks 13a having a predetermined number are selected in order of the oldest access time, and the data of the N reference blocks 23 corresponding to the reference numbers to which the N storage blocks 13a are connected are selected. After each replacement with the data of the storage block 13a, the N storage blocks 13a are converted to the free block 13b. N is a value that can be preset by the user or installer of the computer system as a ratio of the total number of access blocks.

Preferred embodiments of the present invention described above are disclosed to solve the technical problem, and those skilled in the art to which the present invention pertains will be capable of various modifications, changes, additions, etc. within the spirit and scope of the present invention. Such changes, modifications and the like should be considered to be within the scope of the following claims.

10: first computer 11: first connector
12: first auxiliary storage device 13: access block
13a: storage block 13b: free block
14: block management module 15: block management information
20: second computer 21: second connector
22: secondary auxiliary storage device 23: reference block
30: cradle 31: third connector
32: 4th connector

Claims (6)

A first computer 10 including a first CPU, a first main memory device, a first input / output bus, a first connector 11, a display, an input device, and a first auxiliary memory device 12;
A second computer 20 including a second CPU, a second main memory device, a second input / output bus, a second connector 21, and a second auxiliary memory device 22;
A cradle 30 including a connection bus, a third connector 31, and a fourth connector 32; ≪ / RTI >
The first I / O bus is connected to the first CPU, the first main memory device, the first connector 11, the display, the input device, and the first auxiliary memory device 12 to transfer data.
The second input / output bus is connected to the second CPU, the second main memory device, the second connector 21, and the second auxiliary memory device 22 to transfer data.
The connection bus is connected to the third connector 31, the fourth connector 32 to transfer data,
The first auxiliary memory device 12 includes a block management module 14, block management information 15, and a plurality of numbered access blocks 13,
The second auxiliary storage device 22 includes a plurality of reference blocks 23,
When the first computer 10 is used in connection with the second computer 20,
The first computer 10 and the second computer 20 are connected via a wired or wireless network to exchange data, or the first connector 11 is connected to a third connector 31, and the second connector 21 is connected. By connecting to the fourth connector 32, characterized in that the exchange of data,
The block management module 14 changes the data of the access block 13 and the reference block 23, and updates in real time when the block management information 15 is changed,
The access block 13 is divided into a storage block 13a or a free block 13b,
The storage block 13a is a block in which data is stored.
The free block 13b is a block in which no data is stored.
The number of the storage blocks 13a and the free blocks 13b is variable, and the sum of the numbers of the storage blocks 13a and the free blocks 13b corresponds to the total number of the access blocks 13,
The block management information 15 stores a storage block number, a reference block number, a last access time, and synchronization for every storage block 13a.
The storage block number is the number of the storage block 13a,
The reference block number is the number of the reference block 23 synchronized to the storage block 13a,
The last access time is the time of the last access to the storage block 13a,
In the block management method using a computer system, characterized in that the synchronization is stored as T if the data of the storage block 13a is synchronized to the corresponding reference block 23, F if not synchronized,
When a user accesses the storage block 13a with the first computer 10 to change data, whether or not the storage block 13a that changes the data is synchronized is changed to F. .
In the block management method using the computer system of claim 1,
In the state where the first computer 10 is connected to the second computer 20, the number of the reference block 23 to be accessed by the user to the first computer 10 is the number of the block management information 15. When not stored in the reference block number,
If there is a free block (13b) of the connection block 13,
The block management module 14 stores the data of the reference block 23 to be accessed in the free block 13b, thereby converting the free block 13b into a storage block 13a,
If there is no free block 13b of the connection block 13,
The block management module 14 stores the data of the reference block 23 to be accessed in the storage block 13a of which the last access time is the oldest among the storage blocks 13a of which synchronization is T, and the access reference. Updating the last access time of the storage block (13a) storing the data of the block (23).
delete In the block management method using the computer system of claim 1,
When a user creates and stores new data with the first computer 10,
If there is a free block (13b) of the connection block 13,
The block management module 14 stores the new data in the free block 13b, thereby converting the free block 13b into a storage block 13a,
If there is no free block 13b of the connection block 13,
The block management module 14 replaces the data of the storage block 13a having the oldest access time among the storage blocks 13a of which synchronization is T with the new data and stores the new data. Updating the last access time of 13a) and changing the synchronization to F;
In the block management method using the computer system of claim 1,
When the first computer 10 is separated from the second computer 20 and there is a change in synchronization among the storage blocks 13a to F,
When the first computer 10 is connected to the second computer 20,
The block management module 14 replaces data of each reference block 23 corresponding to the storage block 13a having the synchronization status F with data of each storage block 13a having the synchronization status F, and synchronizes the data. Change it to T,
When the first computer 10 is separated from the second computer 20 and there is a newly created storage block 13a,
When the first computer 10 is connected to the second computer 20,
The block management module 14 synchronizes the newly created storage block 13a with the reference block 23 having no data, and changes whether or not the newly created storage block 13a is synchronized to T. Block management method
In the block management method using the computer system of claim 1,
After the user connects and works with the first computer 10 and the second computer 20, one or more of the first computer 10 and the second computer 20 are terminated,
When the user connects the first computer 10 and the second computer 20 to work and then separates the first computer 10 and the second computer 20,
The block management module 14 selects the N storage blocks 13a having a predetermined number in order of the last access time of the storage blocks 13a, and the reference numbers to which the N storage blocks 13a are connected. After replacing the data of the corresponding N reference block 23 with the data of the N storage block 13a, respectively, the N storage block 13a is characterized in that the conversion to the free block (13b) Block management method.

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