KR100950026B1 - System for ASN.1 Based Data Interworking, Apparatus for Data Interworking, Method for ASN.1 Based Data Incoding to transmission for Heterogeneous System and Method for Data Interworking for Heterogeneous System - Google Patents

Abstract

The present invention relates to a system, an apparatus, and a method for interworking data between heterogeneous systems based on Abstract Syntax Notation One (ASN.1). More particularly, the present invention relates to other systems in a system in which the ASN.1 module cannot be mounted in a main module. The present invention relates to a data interworking system, apparatus, and method between heterogeneous systems based on ASN.1 for enabling ASN.1 based communication when data interworking is performed.

ASN.1, ASN.1 engine, standard data exchange, encoding and decoding.

Description

A system and a data interworking device that interoperates data using ASN.1, a method of encoding data to be transmitted to a heterogeneous system using ASN.1, and a data interworking method with a heterogeneous system {System for ASN.1 Based Data Interworking, Apparatus for Data Interworking, Method for ASN.1 Based Data Incoding to transmission for Heterogeneous System and Method for Data Interworking for Heterogeneous System}

The present invention relates to a system, an apparatus, and a method for interworking data between heterogeneous systems based on ASN.1 (ASN.1; Abstract syntax Notation One), and more particularly, an ASN.1 module cannot be mounted in a main module. ASN.1-based heterogeneous system interworking system, apparatus, and method for data communication using an ASN.1-based module that operates separately and performs an encoding and decoding procedure in data interworking between a system and another system It is about.

In general, ASN.1 is a protocol that defines the exchange of data over a standardized network through the International Telecommunication Union (ITU) and is used in the network, information security, mobile and other fields. ASN.1 requires data interworking between individual systems using various operating systems (MS Windows series, Sun Solaris, IBM AIX, HP-UX, Mac OSX, Linux, FreeBSD, etc.), storing data used by each system. It was created to solve the problem of data interpretation error caused by the difference in structure. That is, since the data structures of the operating systems are different from each other, when data is transmitted from one system to another system, the received system may interpret the received data as completely different data. Therefore, in order to solve the above problems, a common data expression grammar was determined, which is ASN.1.

 ASN.1 is a global information exchange standard, established in international and domestic data exchange standards such as, for example, network management, ITS (Intelligent Transport System). In particular, in the case of next-generation traffic systems, the standard definition itself is enacted and published using the ASN.1 marking method.In the case of the next-generation traffic system in Korea, the communication method between traffic centers was enacted by the ASN.1 method. In the communication system between the two countries, legislation and commercialization are delayed. These delays are also caused by technical problems. The terminals used in the next generation transportation systems are vehicle terminals, personal portable terminals, tachographs, bus-mounted devices, electronic board controllers, information repeaters, and model vehicle-mounted information collectors. There are many kinds. Therefore, since the operating system, the development language, and the like are different from each other, it is not easy to use the existing ASN.1 application method.

In addition, currently available ASN.1 tools support only some operating systems such as UNIX, LINUX, Windows, WindowsNT, and WindowsCE, and the development language is also very limited to C, C ++, JAVA, etc. Therefore, in order to use the commercially available ASN.1 tool, the system must use an operating system supporting the ASN.1 tool. On the other hand, in the general development environment of small terminal makers, in terms of cost, convenience, or technical problems, the use of a small operating system, optimization of a small operating system, or use of an operating system without an operating system in the form of an operating system are required. Implement. Therefore, the ASN.1 tool is often not applicable to the small terminal system. In addition, the small terminal systems are not only an operating system, but also a variety of development languages, and thus cannot support even the most used ASN.1 tools such as OSS and Objective. This is true not only for small terminals, but also for various other non-standardized devices and systems. On the other hand, while the role of small terminals in the next generation traffic system, such as a traffic information collector, a user display device, etc., is gradually increasing, while in the conventional technology situation, the small terminals that do not support the ASN.1 tool are in a non-standard form. It is inevitably linked to the traffic center. Such non-standard interworking causes an increase in costs, an increase in development time, installation of additional conversion equipment, and reduction in the application of standards.

The present invention is a main module that occurs in the existing ASN.1 method by mounting a module that operates separately from the main module used in the system to solve the above problems and performs the ASN.1-based encoding and decoding process. Its purpose is to solve problems related to OS, development language, and make it possible to exchange data between all heterogeneous systems in a standard way.

According to an aspect of the present invention,

In the system in which ASN.1 module is not installed in the main module that functions as a main function and interoperates data with other systems using ASN.1, it performs the main function of the system and controls data transmission and reception with other systems. An ASN.1 engine receiving an event notification signal from the main module and converting data by processing an encoding and decoding process of the data using the ASN.1 and transmitting an event response signal to the main module accordingly ; Data of the format used by the main module and ASN.1-based standard structure data (PDU; Protocol Data Unit) received from other systems are received and stored from the main module, and data of the format used by the main module is encoded. ASN.1-based standard structure data (PDU) generated from the system and ASN.1-based standard structure data (PDU) received from the other system are decoded. And a shared memory for data communication with the main module and the ASN.1 engine, which is received from an engine and stored therein, wherein the format of data used by the main module is ASN.1-based standard structure data (PDU). When converting the data into the shared memory, the main module transmits the data of the format used by the main module to the shared memory to be stored. The ASN.1 engine transmits an event notification signal to the ASN.1 engine, and the ASN.1 engine receiving the event notification signal receives and encodes data in a format used by the main module stored in the shared memory, thereby encoding the ASN.1 standard. Convert to structure data (PDU) to transmit and store in the shared memory and to transmit the event response signal to the main module, the main module receiving the event response signal is ASN.1 based standard structure stored in the shared memory When the data PDU is received and the main module converts ASN.1-based standard structure data (PDU) received from another system into data in a format used by the main module, the main module receives from another system. An ASN.1-based standard structure data (PDU) is transmitted to the shared memory for storage and an event notification signal indicating that there is data to be decoded. And the ASN.1 engine 20 receiving the event notification signal receives and decodes the ASN.1 based standard structure data (PDU) stored in the shared memory and uses the main module for decoding. Converts the data into the shared memory, transmits the data to the shared memory, stores the event response signal to the main module, and receives the event response signal from the main module. It is characterized by receiving.

Preferably, the ASN.1 engine includes a signal control unit for receiving an event notification signal signal from the main module and transmitting an event response signal to the main module; A data control unit reading data transmitted from the main module stored in the shared memory and storing data to be transmitted to the main module in the shared memory; A conversion module for receiving data read from the shared memory and encoding and decoding using ASN.1; And control the conversion module so that the data control unit receives data from the main module read from the shared memory and transmits the data to the conversion module to be encoded or decoded according to the event notification signal, and converts the data encoded or decoded by the conversion module. A conversion controller for transmitting to the data controller to be stored in the shared memory; It is made, including.

The shared memory may further include: an attribute information store; And a PDU information store, wherein the attribute information store stores data to be encoded and received and decoded data for transmission, and the PDU information store stores data encoded for transmission and data received from other systems. Characterized in that.

In addition, the main function of the system and includes a main module for controlling data transmission and reception with other systems, and the ASN.1 module is separately installed in a non-standardized system that is not mounted in the main module to provide ASN.1. In an apparatus for interlocking data with another system to be used, the system receives an event notification signal from the main module and accordingly processes the encoding and decoding process of the data using ASN.1 to convert data and convert the event response signal into a main module. An ASN.1 engine to transmit to; Data of the format used by the main module and ASN.1-based standard structure data (PDU; Protocol Data Unit) received from other systems are received and stored from the main module, and data of the format used by the main module is encoded. ASN.1-based standard structure data (PDU) generated from the system and ASN.1-based standard structure data (PDU) received from the other system are decoded. And a shared memory for data communication with the main module 10 and the ASN.1 engine, which are received from an engine and stored therein, wherein the data of the format used by the main module is ASN.1 based on standard structure data. When converting to a PDU, the main module transmits data in a format used by the main module to the shared memory to be stored, and to be encoded. Transmits an event notification signal to the ASN.1 engine 20, and the ASN.1 engine receiving the event notification signal receives and encodes the data in a format used by the main module stored in the shared memory to ASN.1. Converts into standard structure data (PDU) based on the ASN.1 based on the ASN.1 stored in the shared memory by transmitting the event response signal to the main module and storing the event response signal to the main module. When the main module converts the ASN.1-based standard structure data (PDU) received from another system into data of a format used by the main module, the main module ASN.1-based standard structure data (PDU) received from another system is transmitted to the shared memory to be stored, and an event notification that there is data to be decoded Is transmitted to the ASN.1 engine 20, and the ASN.1 engine 20 having received the event notification signal receives and decodes the ASN.1 based standard structure data (PDU) stored in the shared memory to receive the main signal. The module converts the data into a format used by the module, transfers the data to the shared memory, and stores the data. The main module that receives the event response signal is used by the main module stored in the shared memory. The ASN.1 engine may be a module implemented in software or a module implemented in hardware.

A method of encoding data to be sent to a heterogeneous system using ASN.1, the method comprising: transmitting, by a main module, data to a shared memory and storing the data to an ASN.1 engine; Generating an Protocol Data Unit (PDU) by receiving and encoding the data stored in the shared memory when the ASN.1 engine receives the event notification signal; Transmitting, by the ASN.1 engine, the PDU to the shared memory and storing the event response signal to the main module; Receiving a PDU stored in the shared memory when the main module receives an event response signal; And sending, by the main module, the PDU.

In addition, in the data interworking method with heterogeneous systems using ASN.1,

Receiving a PDU from another system; Transmitting the received PDU to a shared memory and transmitting an event notification signal to an ASN.1 engine when the PDU is transmitted; Receiving a PDU stored in the shared memory and decoding the same using an ASN.1 engine; Transmitting and storing the decoded data by using the ASN.1 engine to the shared memory, and transmitting an event response signal to the main module when the decoded data is transmitted; Transmitting decoded data stored in the shared memory to a main module; Characterized in that it comprises a.

The present invention having the configuration as described above

With the ASN.1 engine that performs the encoding and decoding process of data based on ASN.1, there is an effect that ASN.1 based standard communication can be performed in the situation of data communication between different systems.

Furthermore, by using the ASN.1 engine that operates separately from the main module that functions as the main function of the system, the ASN.1 system operating system is commonly used in the case of data communication between different systems. ASN.1 based standard data conversion using the ASN.1 engine even if the tool is not available or the ASN.1 module cannot be mounted directly on the main module using a small operating system, so that only non-standard communication can be performed. And exchangeable effects.

In addition, the ASN.1 engine may be implemented in the form of a hardware module, that is, a programmable semiconductor chip or an application specific semiconductor (ASIC), an IC circuit, and a microchip, and manufactured as an independent device from the system. In addition, the ASN.1 engine can be easily applied to a small system that does not use an existing operating system.

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

1 shows a schematic configuration of a system for interlocking data using an ASN.1 engine according to a preferred embodiment of the present invention.

Referring to the drawings, the system consists of a main module 10, a shared memory 30, and an ASN.1 engine 20.

The main module 10 is installed in any system and is a software or hardware module for performing the main functions of the system. For example, the main module 10 may be a non-standard vehicle navigation system, a function module of a non-standard driving recorder, and the like. Outside non-standardized terminals can be the modules needed to operate. The main function of the system described above refers to a function performed in order to achieve the original purpose of various systems commonly used. The main module 10 may be a kind of program that runs on commonly used operating systems (eg, MS Windows series, Sun Solaris, IBM AIX, HP-UX, Mac OSX, Linux, FreeBSD, etc.) Instead of running on an operating system, it may be a separate program that uses its own data storage method. In addition, the main module 10 may be a hardware module that implements the programs in hardware. The main module exchanges data used with other systems through a data communication method that is commonly used.

The ASN.1 engine 20 is a module that operates ASN.1 separately in software or hardware, and is not involved in the basic operation of the system, and encodes and decodes ASN.1 based data, and transmits data. And an apparatus for performing an operation of receiving. In addition, the ASN.1 engine 20 may be executed separately regardless of the operating system and program language used by the main module 10. As described above, since the ASN.1 engine 20 is executed separately and performs ASN.1-based data encoding and decoding, the ASN.1 engine 20 may be used in a system that cannot use a commonly used ASN.1 tool.

The ASN.1 engine 20 is composed of one software that operates separately, and may be a module implemented in the form of software for performing the above-described process. The implemented module, that is, implemented in the form of a semiconductor chip, may be mounted on the same circuit board as the main module 10 or a circuit board adjacent thereto. For example, it is implemented in the form of a programmable semiconductor chip or an application specific semiconductor (ASIC), an IC circuit, and a microchip, and is installed in a system in which the main module is installed and shares data with the main module 10 to share the ASN. It is possible to perform an encoding and decoding process of .1-based data, but is not limited thereto. In addition, it may be configured as a separate independent device, used in combination with the completed system.

Meanwhile, the ASN.1 engine 20 is basically installed in the same system as the main module 10, but is not limited thereto. In addition, the ASN.1 engine 20 may be additionally installed in the system in which the main module 10 is installed. It may be an add-on type of software used or a module implemented in hardware.

The shared memory 30 exchanges data between the main module 10 and the ASN.1 engine 20 and temporarily stores the data. The shared memory 30 is divided into an attribute information store 31 and a PDU information store 32 according to the type and function of data to be processed.

The attribute information storage 31 exchanges data with the main module 10 and the ASN.1 engine 20 and stores data of a structure used by the main module 10. That is, the attribute information storage unit 31 stores the data transmitted from the main module 10 and transmits the data back to the ASN.1 engine 20 when the ASN.1 engine 20 requests data. .

The PDU information store 32 is capable of data communication with the ASN.1 engine 20 and the main module 10. The PDU information store 32 receives and stores the data converted from the ASN.1 engine 20, that is, the PDU, and retransmits the data to the main module 10 at the request of the main module 10.

In the shared memory 30, the attribute information storage 31 and the PDU information storage 32 are described as operating in the same memory, but may be configured as different memories. In addition, since the shared memory 30 is intended to store and transfer data, the shared memory 30 may be configured as a recording device that is commonly used, such as a hard disk, in addition to the memory.

In the case of the encoding in which the main module 10 prepares data of its own format as standard data and sends it to the outside, the main module 10 transmits the data in a standard data structure based on ASN.1 based on PDU (Protocol). In order to convert to a data unit, it is first transferred to the shared memory 30. Here, the PDU represents a bundle of information, that is, a data arrangement, used when transferring information between systems, and the ASN.1 international protocol standardizes this arrangement to unify the structure of data when exchanging information between heterogeneous systems. The shared memory 30 temporarily stores the received data in the shared memory 30, and the main module 10 transmits an event notification signal to the ASN.1 engine 20. When the ASN.1 engine 20 receives the event notification signal, the ASN.1 engine 20 receives data stored in the shared memory 30. The ASN.1 engine 20 encodes the data received from the shared memory 30 to generate a PDU. The ASN.1 engine 20 transmits the generated PDU to the shared memory 30. The shared memory 30 temporarily stores the received PDU. The ASN.1 engine 20 transmits an event response signal to the main module 10. When the main module 10 receives the event response signal, the main module 10 receives the PDU stored in the shared memory 30. The main module 10 utilizes standard data by transferring the received PDUs to another system or recording them in a separate storage device.

When the main module 10 receives data from another system, since the received data has a PDU structure, the main module 10 performs a decoding process as opposed to the encoding process. First, the main module 10 transmits the received PDU data to the shared memory 30 and transmits an event notification signal to the ASN.1 engine 20. The shared memory 30 temporarily stores the received PDU data. When the ASN.1 engine 20 receives an event notification signal from the main module 10, the ASN.1 engine 20 receives PDU data stored in the shared memory 30. The ASN.1 engine 20 decodes the PDU data to generate decoded data, and transmits the decoded data to the shared memory 30 again. The ASN.1 engine 20 transmits an event response signal to the main module 10. When the main module 10 receives the event response signal, the main module 10 receives and uses the decoded data stored in the shared memory 30.

2 is a block diagram of the ASN.1 engine 20 and illustrates an internal structure and processing method of the ASN.1 engine 20 to provide ASN.1 based data encoding and decoding functions.

The ASN.1 engine 20 includes a signal controller 23, a data controller 22, a conversion controller 21, a conversion module 26, a temporary property storage 24, and a temporary PDU information storage 25. have.

The signal controller 23 generates and transmits a signal so that the ASN.1 module 20 can directly exchange signals with the main module 10, and receives a signal transmitted from the main module 10. That is, it receives an event notification signal indicating that there is data to be encoded and decoded from the main module 10, and transmits an event response signal to the main module 10 after the encoding and decoding process is completed.

The data controller 22 functions to exchange data through data communication between the ASN.1 engine 20 and the shared memory 30.

The conversion control unit 21 controls the encoding and decoding process of the received data.

The conversion module 26 is composed of an encoder 28 for encoding data and a decoder 27 for decoding under the control of the conversion control unit.

The temporary property storage 24 and the temporary PDU information storage 25 function to temporarily store data to be encoded and decoded.

The main module 10 transmits an event notification signal to the ASN.1 engine 20 when there is PDU information to be converted. When the signal controller 23 receives the event notification signal transmitted from the main module 10, the signal controller 23 notifies the data controller 22 that the event notification signal has been received. When the data controller 22 recognizes that the event notification signal has been received, the data controller 22 reads data stored in the shared memory 30. The data controller 22 transmits the data read from the shared memory 30 to the conversion controller 21. The conversion control unit 21 instructs the data to be stored in the temporary attribute information storage 25 and transmitted to the conversion module 26 for encoding. The conversion module 26 encodes the data to generate a PDU and transmits the PDU to the conversion controller 21. The conversion control unit 21 transmits the transmitted PDU to the data control unit 22. The data controller 22 transmits the transmitted PDU to the shared memory 30 and informs the signal controller 23 that the PDU has been transmitted. The signal controller 23 generates an event response signal informing that the PDU has been transmitted and transmits the generated event response signal to the main module 10. When the main module 10 receives the event response signal, the main module 10 reads the PDU stored in the shared memory 30. The data encoding process is performed in the above manner.

Meanwhile, a decoding process of converting PDUs received from heterogeneous systems into data for use in the present system is performed as follows.

The main module 10 transmits an event notification signal to the ASN.1 engine 20 when there is PDU information to be converted. When the signal controller 23 receives the event notification signal transmitted from the main module 10, the signal controller 23 notifies the data controller 22 that the event notification signal has been received. When the data controller 22 recognizes that the event notification signal has been received, the data controller 22 reads data stored in the shared memory 30. The data controller 22 transmits the read data to the conversion controller 21. The conversion control unit 21 instructs the data to be stored in the temporary PDU information storage and transmitted to the conversion module 26 for decoding. The conversion module 26 decodes the data to generate data used in the system and transmits the data to the conversion control unit 21. The conversion control unit 21 transmits the data transmitted from the conversion module 26 to the data control unit 22. The data controller 22 transmits the transmitted data to the shared memory 30 and informs the signal controller 23 that the data has been transmitted. The signal controller 23 generates an event response signal informing that the data has been transmitted and transmits it to the main module 10. When the main module 10 receives the event response signal, the main module 10 reads data stored in the shared memory 30. The decoding process of the data is performed in the above manner.

3 shows the internal structure of a shared memory according to an embodiment of the present invention.

The shared memory is divided into an attribute information storage 31 and a PDU information storage 32. An object IDentifier (OID) is an identifier for distinguishing information and may be composed of a plurality of attributes. The attribute information storage 31 is composed of an array of an OID storage 33 for storing the OID, a number storage 34 for storing the number of attributes, and an attribute value storage 35. The PDU information storage 32 is composed of an OID storage 36, a length storage 37, and a PDU storage 38. Shared memory refers to a shared space that the main module 10 and the ASN.1 engine 20 can access in common, and the actual location does not necessarily need to be located in the memory as described above. Although the decoding and encoding process is shown in FIG. 3 as being performed between the attribute information store and the PDU information store, this omits the process of the ASN.1 engine 20, and the actual encoding and decoding is performed by the ASN.1 engine. On 20.

1 is a data exchange method using the ASN.1 engine according to a preferred embodiment of the present invention.

2 is an ASN.1 engine structure diagram according to a preferred embodiment of the present invention.

3 is a shared memory structure diagram in accordance with a preferred embodiment of the present invention.

* Explanation of Signs of Major Parts of Drawings *

10: main module 20: ASN.1 engine

21: conversion control unit 22: data control unit

23: signal control unit 24: temporary attribute information storage

25: temporary PDU information storage 26: conversion module

27: decoder 28: encoder

30: shared memory 31: attribute information storage

32: PDU information storage 33: OID (Object IDentifier) storage

34: count storage 35: attribute value storage

36: OID Store 37: Length Store

38: Protocol Data Unit (PDU) storage

Claims (16)

In a system in which the ASN.1 module is not installed in the main module which functions as a main function, and uses ASN.1 to link data with other systems, A main module that performs a main function of the system and controls data transmission and reception with another system to communicate data; An ASN.1 engine that receives an event notification signal from the main module and accordingly processes the encoding and decoding process of the data using ASN.1 to convert the data and transmits an event response signal to the main module; Data of the format used by the main module and ASN.1-based standard structure data (PDU; Protocol Data Unit) received from other systems are received and stored from the main module, and data of the format used by the main module is encoded. ASN.1-based standard structure data (PDU) generated from the system and ASN.1-based standard structure data (PDU) received from the other system are decoded. And a shared memory for receiving data from an engine and storing data in communication with the main module 10 and the ASN.1 engine. When converting the data of the format used by the main module into ASN.1-based standard structure data (PDU), The main module transmits the data of the format used in the main module to the shared memory to be stored and transmits an event notification signal to the ASN.1 engine 20 that there is data to be encoded, and receives the event notification signal. The ASN.1 engine receives and encodes data in a format used by the main module stored in the shared memory, converts the data into ASN.1-based standard structure data (PDU), transmits the data to the shared memory, and stores the event response signal. Transmits to the main module, the main module receiving the event response signal receives ASN.1-based standard structure data (PDU) stored in the shared memory, When the main module converts ASN.1-based standard structure data (PDU) received from another system into data of a format used by the main module, The main module transmits the ASN.1-based standard structure data (PDU) received from another system to the shared memory to be stored and transmits an event notification signal to the ASN.1 engine 20 indicating that there is data to be decoded. The ASN.1 engine 20 receiving the event notification signal receives the ASN.1-based standard structure data (PDU) stored in the shared memory, decodes the data, and converts the data into a format used by the main module. ASN, characterized in that for transmitting and storing in the memory, and transmits the event response signal to the main module, the main module receiving the event response signal receives the data of the format used by the main module stored in the shared memory .1 A system that links data with other systems using .1. The method of claim 1, The ASN.1 engine, A signal controller which receives an event notification signal signal from the main module and transmits an event response signal to the main module; A data control unit reading data transmitted from the main module stored in the shared memory and storing data to be transmitted to the main module in the shared memory; A conversion module for receiving data read from the shared memory and encoding and decoding using ASN.1; And In response to the event notification signal, the data controller receives the data from the main module read from the shared memory and transfers the data to the conversion module to control the conversion module to be encoded or decoded, and share the data encoded or decoded by the conversion module. A conversion control unit for transmitting to the data control unit to be stored in the memory; A system for interlocking data with other systems using ASN.1, characterized in that it comprises a. delete delete delete delete delete It is a main function of the system and includes a main module that controls data transmission and reception with other systems and communicates with other systems, and the ASN.1 module is separately installed in a non-standardized system that is not mounted in the main module. In the device for interlocking data with the system, An ASN.1 engine that receives an event notification signal from the main module and accordingly processes the encoding and decoding process of the data using ASN.1 to convert the data and transmits an event response signal to the main module; ASN.1 ASN.1 based standard structure data (PDU) received from another system and stored in the form of data used by the main module from the main module, and encoded by the data of the format used by the main module .1 based standard structure data (PDU) and ASN.1 based standard structure data (PDU) received from other systems are decoded and received from the ASN.1 engine in the form of data used by the main module. And a shared memory configured to store data in communication with the main module 10 and the ASN.1 engine. When converting the data of the format used by the main module into ASN.1-based standard structure data (PDU), The main module transmits the data of the format used in the main module to the shared memory to be stored and transmits an event notification signal to the ASN.1 engine 20 that there is data to be encoded, and receives the event notification signal. The ASN.1 engine receives and encodes data in a format used by the main module stored in the shared memory, converts the data into ASN.1-based standard structure data (PDU), transmits the data to the shared memory, and stores the event response signal. To the main module, so that the main module receiving the event response signal receives ASN.1-based standard structure data (PDU) stored in the shared memory, When the main module converts ASN.1-based standard structure data (PDU) received from another system into data of a format used by the main module, The main module transmits the ASN.1-based standard structure data (PDU) received from another system to the shared memory to be stored and transmits an event notification signal to the ASN.1 engine 20 indicating that there is data to be decoded. The ASN.1 engine 20 receiving the event notification signal receives the ASN.1-based standard structure data (PDU) stored in the shared memory, decodes the data, and converts the data into a format used by the main module. And transmit the event response signal to the main module so that the main module receiving the event response signal receives data of a format used by the main module stored in the shared memory. Device that interoperates with other systems using ASN.1. The method of claim 8, The ASN.1 engine, A signal controller which receives an event notification signal signal from the main module and transmits an event response signal to the main module; A data control unit reading data transmitted from the main module stored in the shared memory and storing data to be transmitted to the main module in the shared memory; A conversion module for receiving data read from the shared memory and encoding and decoding using ASN.1; And In response to the event notification signal, the data controller receives the data from the main module read from the shared memory and transfers the data to the conversion module to control the conversion module to be encoded or decoded, and share the data encoded or decoded by the conversion module. A conversion control unit for transmitting to the data control unit to be stored in the memory; Apparatus for interworking data with other systems using ASN.1, characterized in that comprises a. delete The method of claim 8, The ASN.1 engine, Device for interworking data with other systems using ASN.1, characterized in that the module implemented in software. The method of claim 8, The ASN.1 engine, Device for interworking data with other systems using ASN.1, characterized in that the module implemented in hardware. delete delete delete delete

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