KR100311315B1 - Protocol processing system using a high-speed data transmission path - Google Patents

Abstract

According to the present invention, a plurality of physical / link layer processing units and a plurality of protocol processing units for processing data for various types of protocols and a plurality of protocol processing units are interconnected using standard interfaces, thereby efficiently converting functions between protocols. The present invention relates to a multi-protocol processing system using a high speed data transmission path, comprising a plurality of physical / link layer processing blocks including a plurality of physical / link layer processing units having the same protocol format, and each physical / link layer processing block. Is a physical / link layer processing group for processing protocol data having different formats; A protocol processing group consisting of a plurality of protocol processing units for converting and outputting protocol data of different formats provided from a physical / link layer processing group; A high speed data transfer path for data transmission between the physical / link layer processor and the protocol processing group; A system storage device configured to store and execute execution software for processing protocol data of each protocol processing unit, subscriber authentication data, and information on each physical / link layer processing unit as a database; By including the system management unit which copies the execution software stored in the system storage device and distributes / transmits it to each protocol processing unit, it is possible to design an exchange system to support multiple protocols simultaneously, and to develop software to accommodate each protocol data. There is an effect to improve the efficiency of.

Description

PROTOCOL PROCESSING SYSTEM USING A HIGH-SPEED DATA TRANSMISSION PATH}

The present invention relates to a protocol processing system, and more particularly, to a protocol processing system using a high speed data transfer path capable of processing various protocol data using a high speed data transfer path.

As is well known, a communication protocol called a communication protocol is required to perform data exchange (transmission and reception) of voice, video, text, etc. between wired (normal telephone lines, leased lines, optical cables, etc.) or wireless communication devices. As the protocol, for example, the AO protocol, the DI protocol, the Internet protocol, the ATM protocol, the signaling protocol. X.25 protocol.

On the other hand, in the conventional general exchanger that processes and transmits data using these various protocols, it is common to accept only one protocol and transmit data. However, according to the development of a communication system, various different protocols can all be accommodated. Multiprotocol processing capabilities have been required. In other words, there is a demand for a protocol processing system capable of converting a specific protocol into another type of protocol and constructing a new layer.

However, in order to perform the multi-protocol processing function as described above in the conventional general exchange, there is a problem in that all protocol software as well as the related protocol processing software must be redesigned, resulting in high cost and personnel. There is a problem.

Accordingly, the present invention is to solve the above problems of the prior art, comprising a plurality of physical / link layer processing unit and a plurality of protocol processing unit for processing various kinds of protocols, each of the physical / link layer processing unit and protocol processing unit The purpose of the present invention is to provide a protocol processing system using a high-speed data transfer path capable of efficiently performing a conversion function between protocols by interconnecting the s with a standard interface.

In order to achieve the above object, the present invention provides a multi-communication protocol processing system for converting and transmitting protocol data of different formats to each other, wherein a plurality of physical / link layers including a plurality of physical / link layer processing units having the same protocol format are provided. A physical / link layer processing group configured to include a processing block, wherein each physical / link layer processing block processes protocol data having different formats; A protocol processing group composed of a plurality of protocol processing units for converting and outputting the protocol data of different formats provided from the physical / link layer processing group; A high speed data transfer path for data transmission between the physical / link layer processing group and the protocol processing group; A system storage device configured to store execution software for processing protocol data of each protocol processor, subscriber authentication data, and information on each physical / link layer processor in a database; It provides a multi-communication protocol processing system using a high-speed data transmission path including a system management unit for copying the execution software stored in the system storage device to distribute / transmit to each protocol processing unit.

1 is a block diagram showing the configuration of a protocol processing system using a high speed data transmission path according to a preferred embodiment of the present invention;

2 is a flowchart illustrating a process up to driving a protocol processing program for performing data processing in the protocol processing system according to the present invention;

3 is a flowchart illustrating an example of a data processing process between a physical / link layer processing unit and a protocol processing unit of the protocol processing system according to the present invention;

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

100: physical / link layer processing group 200: high speed data transfer path

300: protocol processing group 400: system management unit

500: System Storage

The above and other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

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

1 is a diagram illustrating a multi-protocol processing system using a high speed data transmission path according to a preferred embodiment of the present invention, in which a physical / link layer processing group 100, a high speed data transmission path 200, and a protocol processing group 300 are shown. ), The system manager 400, and the system storage device 500.

Referring to the figure, the physical / link layer processing group 100 includes a plurality of physical / link layer processing units 110, 120, ..., 170 for processing data of different protocols. The high speed data transfer path 200 serves as a data transmission path between the physical / link layer processor group 100 and the protocol processing group 300.

The protocol processing group 300 includes a plurality of protocol processing units 310, 320, 340, 350, 360, and 370 and common storage devices 315, 325,..., 365 for storing shared data between the protocol processing units. It is composed.

The system manager 400 reads a database stored in the system storage device 500, transmits and loads a protocol processing execution file to each protocol processor 310, 320,. Subscriber authentication information and service class information, etc., are copied and distributed to each common storage device 315, 325, ..., 365 in each protocol controller 310, 320, ..., 370, and each protocol processor 310 Service information and information (processing contents and distribution data, etc.) for each of the physical / link layer processing units 110, 120, ... 170 corresponding to, 320,..., 370. Configure as a separate database in 365).

Meanwhile, each of the common storage devices 315, 335, 345, 345, and 365 included in the protocol processing group 300 have the same address structure and the same physical control right, so that each protocol processing unit 310, 320,..., 360 is used. Ensure that each protocol processing program running on is compatible with each other. In other words, any protocol that has a different protocol processing program operating in an arbitrary protocol processing unit by unifying the interface method between each protocol processing unit 310, 320, ..., 360 and each of the common storage devices 315, 335, ..., 365. It can also be operated in the processing unit.

FIG. 2 is a diagram illustrating a process until the protocol processing group 300 drives a protocol processing program for performing data processing with the physical / link layer processing group 100 in the above-described multi-protocol processing system. Referring to 1 and 2 as follows.

First, when the system management unit 400 is activated in the above-described protocol processing system (S201), each protocol processing unit 310, 320, ..., 370 in the protocol processing group 300 performs a program transmission request signal for performing protocol processing. Generate and transmit to the system management unit 400 through the high-speed data transmission path 200 (S203).

At this time, the system manager 400 determines a protocol type corresponding to each protocol processor 310, 320, ..., 370 from the program transmission request signals of the protocol processor 310, 320, ..., 370 ( S205), each protocol processing program stored in the system storage device 500 is read (S207), and then a program corresponding to each protocol processing unit 310, 320, ..., 370 through the high speed data transfer path 200, i.e., Each protocol processing program corresponding to the type of each protocol processor 310, 320, ..., 370 determined in step S205 described above is transmitted / distributed.

Accordingly, each protocol processor 310, 320,..., 370 receives a protocol processing program provided through the high speed data transmission path 200, and stores the protocol processing program in each common storage device 315, 325,..., 365. By executing, the protocol data provided from the physical / link layer processing group 100 can be processed through the high speed data transmission path 200.

3 shows the first and second physical / link layer processing units 110 and 120 and the first and the first in the state where the protocol processing program of each protocol processing unit 310, 320,..., 370 is completed through the above-described process. And a data processing process between the second protocol processing units 310 and 320, the operation process will be described in detail with reference to the accompanying drawings.

First, the first protocol processor 310 and the second protocol processor 320 correspond to the second physical / link layer processor 120 with the first type of protocol data provided from the first physical / link layer processor 110. A function of converting to the second type of protocol data, which is any one of the plurality of first physical / link layer processing unit (110-1, 110-2, ..., 110-n), for example When the first type of protocol data provided from the first physical / link layer processor 110-1 is provided to the first protocol processor 310 through the high speed data transmission path 200, the first protocol processor 310 receives the received protocol data. In operation S301, network layer protocol processing is performed on the received first type of protocol data (S303), and only pure transmission data from which header information is removed is extracted (S305). In operation S307, it is stored. Subsequently, the first protocol processor 310 notifies the second protocol processor 320 that the information stored in the first common storage device 315 exists (S309).

Meanwhile, the second protocol processor 320 reads data stored in the first common storage device 315 in response to the notification from the first protocol processor 310 (S311), and transmits the physical data to transmit the read data. The link layer processing unit, for example, converts the second type of protocol data corresponding to the second physical / link layer processing unit 120 into new network layer protocol data (S313), and then converts the converted data into a high-speed data transmission path ( In operation S315, the second physical / link layer processor 120 transmits the information to the second physical / link layer processor 120.

Unlike the above-described process, when the data provided from the second physical / link layer processing unit 120 is provided to the second protocol processing unit 320 through the high speed data transmission path 200, the above process is reversed. The converted data is transferred to the first physical / link processor 110.

Meanwhile, when the third physical / link layer processor 130, the third call processor 330-1, and the third user processor 330-2 are divided into a control area and a user area for call processing in a protocol, Alternatively, processing is performed when data transfer is possible through link layer processing. This type of data processing structure is a data processing structure when two types of protocols exist at the same time, and the representative example is ISDN.

In detail, first, when the control area and the user area are divided, a call processing process by the third call processing controller 330-1 and a user processing process by the third user processing unit 330-2 for protocol processing. In this case, the second common storage device 335 is used as a database for service authentication information, and is used for signal transmission between the third control processor 330-1 and the third user processor 330-2. do.

In the case where data can be transmitted through link layer processing, a link access procedure for frame mode bearer service (LAPF) may be used. In this case, the third call processing controller 330-1 and the third user processor 330-2 may be used. The data transmitted and received is only information for protocol management, and the actual data transmission path is provided to the high speed data transmission path 200 via, for example, the third physical / link layer processing unit 130-1, and then again any other physical. Only the path of the / link layer processor (eg, the third physical / link layer processor 130-2) is used.

Meanwhile, the fourth physical / link layer processing unit 140-1, 140-2,..., 140-n and the fourth protocol control unit 340-1, 340-2,. The same protocol is used as in the physical / link layer processing unit 130, but data processing is required when parameter supplementation is required after the analysis process up to the network layer like the X.25 protocol, that is, when the same data needs to be redesigned. The operation process is the same as FIG. 3 described above.

In detail, any physical / link layer processing unit of the plurality of fourth physical / link layer processing units 140-1, 140-2,..., 140-n, for example, a fourth physical / link layer processing unit ( When the fourth type of protocol data provided from 140-1 is provided to the fourth protocol processor 340-1 through the high speed data transmission path 200, the fourth protocol processor 340-1 receives the fourth protocol processor 340-1. By performing network layer protocol processing on the type of protocol data, only pure transmission data from which header information is removed is extracted. Subsequently, the extracted data is stored in the third common storage device 345 and the fourth protocol processing unit 340-2 notifies that the information stored in the third shared storage device 345 exists.

Meanwhile, the fourth protocol processor 340-2 reads the data stored in the third common storage device 345 in response to the notification from the fourth protocol processor 340-1, and compensates the read data according to the parameter supplement. After the redesign process, the data is transferred to another fourth physical / link layer processor, for example, the fourth physical / link layer processor 140-2, through the high speed data transmission path 200.

Unlike the above-described process, when the data provided from the fourth physical / link layer processing unit 140-2 is provided to the fourth protocol processing unit 340-2 through the high speed data transfer path 200, the above-described process is performed. The fourth protocol processor 340-1 performs a data redesign process such as supplementing the received parameters by performing the reverse process, and then the fourth physical / link layer processor 140-1 through the high speed data transfer path 200. ).

Finally, the fifth, sixth, and seventh physical / link layer processing units 150, 160, and 170, and the fifth, sixth, and seventh protocol control units 350, 360, and 370, respectively, type 5 and type 6 protocol data. Is combined to convert to type 7 data. In this case, the protocol data of the type 5 and the type 6 processed by the fifth, sixth, and seventh protocol controllers 350, 360, and 370 may be transferred to the seventh through the adjacent fourth or fifth common storage device 355 or 365. The protocol conversion unit 370 is transferred to a protocol conversion function corresponding to the protocol of type 7.

The communication protocol of the fifth physical / link layer processing unit 150 and the fifth protocol processing unit 350 is AO (Always On) protocol, and the communication of the sixth physical / link layer processing unit 160 and the sixth protocol processing unit 360 is performed. If the protocol is a DI (Dynamic ISDN) protocol and the communication protocols of the seventh physical / link layer processing unit 170 and the seventh protocol processing unit 370 are Internet protocols (TCP / IP), the operation thereof will be described in detail. Same as

First, the fifth physical / link layer processing unit 150 performs a matching function for the AO protocol to transmit data for transmission to the Internet network, and analyzes and removes link layer header information of the AO protocol data to thereby transmit the high speed data. Through the fifth protocol processor 350 is transmitted. The fifth protocol processor 350 stores the AO protocol data received through the high speed data transfer path 200 in the fourth common storage device 355 and notifies the seventh protocol processor 370 of the AO protocol data.

The seventh protocol processor 370 notified of the information received from the fifth protocol processor 350 converts the data stored in the fourth common storage device 355 into Internet protocol data to establish the high speed data transfer path 200. Transfer to the seventh physical / link layer processing unit 170 through.

On the contrary, if the DI protocol data from the sixth physical / link layer processing unit 160 is received by the sixth protocol processing unit 360 through the high speed data transfer path 200 after the matching function is performed, the sixth protocol processing unit The 360 stores the received data in the fifth common storage device 365 and notifies the seventh protocol processor 370 of this. In response, the seventh protocol processor 370 reads the data stored in the fifth common storage device 365 and transmits the data stored in the fifth common storage device 365 to the seventh physical / link layer processor 170 through a high speed data transfer path.

On the other hand, in contrast to each of the above-described process, the process for converting the Internet protocol data to DI protocol data to transmit the transmission through the opposite path to the above process. In detail, if the Internet protocol data from the seventh physical / link layer processing unit 170 is received by the seventh protocol processing unit 370 through the high speed data transmission path 200 after the matching function is performed, the seventh protocol The processor 370 stores the received data in the fifth common storage device 365 and notifies the sixth protocol processor 360 that the received data exists. In response, the sixth protocol processor 360 reads the data stored in the fifth common storage device 365 and transmits the data stored in the fifth common storage device 365 to the sixth physical / link layer processor 160 through the high speed data transfer path. Internet protocol data from the / link layer processing unit 170 is converted into DI protocol data and transmitted to the sixth physical / link layer processing unit 160.

As a result, data conversion and transmission for different types of protocols are possible through respective processes as described above.

As described above, according to the present invention, a plurality of protocol processing units and a physical / link layer processing unit for processing different types of protocol data are connected through a high-speed data transmission path, and each protocol processing unit unites the interface scheme of each protocol. By enabling the data conversion between them, it is possible to design an exchange system to support multiple protocols at the same time, and to improve the efficiency of development by reusing software for accommodating each protocol data. .

Claims (4)

In a multi-communication protocol processing system for converting protocol data of different formats to each other, It includes a plurality of physical / link layer processing block composed of a plurality of physical / link layer processing unit having the same protocol format, each physical / link layer processing block is a physical / link for processing protocol data having a different format Hierarchical processing group; A protocol processing group composed of a plurality of protocol processing units for converting and outputting the protocol data of different formats provided from the physical / link layer processing group; A high speed data transfer path for data transmission between the physical / link layer processing group and the protocol processing group; A system storage device configured to store execution software for processing protocol data of each protocol processor, subscriber authentication data, and information on each physical / link layer processor in a database; And a system manager for copying the execution software stored in the system storage and distributing / transmitting each protocol processor. The method of claim 1, wherein the physical / link layer processing group, A first physical / link layer processing block including a plurality of first physical / link layer processing units for transmitting and receiving data of a first protocol type through the high speed data transmission path, and data of a second protocol type through the high speed data transmission path; A second physical / link layer processing block including a plurality of second physical / link layer processing units for transmitting and receiving a plurality of physical and link layer processing units, and a plurality of third physical / link layer processing units for transmitting and receiving data in a third protocol format through the high speed data transmission path. A fourth physical / link layer processing block configured of a third physical / link layer processing block configured, a plurality of fourth physical / link layer processing units configured to transmit and receive data of a fourth protocol format through the high speed data transmission path, and the high speed A plurality of fifth physical / link layer processing units configured to transmit and receive data in a fifth protocol format through a data transmission path. A sixth physical / link layer processing block comprising a fifth physical / link layer processing block, a plurality of sixth physical / link layer processing units for transmitting and receiving data in a sixth protocol format through the high speed data transmission path, and the high speed A seventh physical / link layer processing block including a plurality of seventh physical / link layer processing units for transmitting and receiving data in a seventh protocol format through a data transmission path, The protocol processing group, Receive the data of the first protocol format provided through the high speed data transmission path and store the data in the first common storage device, and store the data of the second protocol format stored in the first common storage device in the first protocol format. A first protocol processor for converting the data into the high speed data transmission path, receiving the data of the second protocol format provided through the high speed data transmission path, and storing the data in the first common storage device; A second protocol processor for converting the data of the first protocol format stored in the common storage device into the data of the second protocol format and transmitting the data of the third protocol format through the high speed data transmission path; Perform call processing on data and store it in the second common storage device And a user processing unit configured to perform user authentication processing on the data of the third protocol format through the high speed data transmission path and store the data in the second common storage device. A third protocol processor for transmitting the call processing information and the user authentication processing information for the high speed data transmission path, and data of the fourth protocol format provided through the high speed data transmission path to a third common storage device. A fourth protocol processing unit comprising first processing means for storing and second processing means for performing parameter supplement and data redesign process for the stored data of the fourth protocol format and transmitting it to the high speed data transmission path; Of the fifth protocol format provided via a delivery path A fifth protocol processor configured to receive the data, store the data in a fourth common storage device, convert data of the seventh protocol format stored in the fourth common storage device into data of the fifth protocol format, and transmit the data to the high speed data transmission path. And receiving the data of the sixth protocol format provided through the high speed data transmission path and storing the data in the fifth common storage device, and storing the data of the seventh protocol format stored in the fifth common storage device in the sixth protocol. A sixth protocol processor for converting the data into a data format and transmitting the data in the high speed data transmission path, and receiving the data in the seventh protocol format provided through the high speed data transmission path to store the fourth common storage device or the fifth common storage. Selectively storing in a device, and storing the fourth common storage device or the fifth common storage device. And a seventh protocol processor configured to convert the data of the fifth protocol format or the data of the sixth protocol format stored in the apparatus into the data of the seventh protocol format and transmit the data to the high speed data transmission path. Multiple Communication Protocol Processing System Using High Speed Data Transmission Path. The method according to claim 2, wherein each of the common storage devices has a high-speed data transmission path, wherein the software operating in each protocol processor is compatible by unifying an interface scheme so as to have the same address structure and the same physical control right. Multiple communication protocol processing system using. The system management unit according to any one of claims 1 to 3, wherein the system manager comprises information on protocol information and protocol format of each protocol processor corresponding to each physical / link layer processing block, and information on the distributed / transmitted software. Multi-communication protocol processing system using a high-speed data transmission path, characterized in that for transmitting to the common storage device database.