KR100480951B1 - Serial line multiplexer interface apparatus - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a multiple access communication apparatus in which one physical channel (hereinafter referred to as a "single physical channel") is extended to a plurality of virtual channels.

2. The technical problem to be solved by the invention

The present invention extends a single physical channel connecting two CPUs to a plurality of virtual channels to provide a desired function, program, and service simultaneously through each virtual channel. To provide the purpose.

3. Summary of Solution to Invention

The present invention provides a multi-access communication apparatus in which one physical channel is extended to a plurality of virtual channels, wherein the first virtual channel for generating n (n is a natural number) first virtual channels that can be used by an external first central processing unit. 1 virtual channel generating means; First virtual channel merging means for merging data received through the n first virtual channels generated by the first virtual channel generating means; First virtual channel distribution means for analyzing first received data and distributing the first received data to a corresponding first virtual channel among the n first virtual channels generated by the first virtual channel generating means; First communication means for transmitting first received data received through the single physical channel to the first virtual channel distribution means, or transmitting data received from the first virtual channel merging means through the single physical channel; Second virtual channel generating means for generating n second virtual channels usable by an external second central processing unit; Second virtual channel merging means for merging data received through the n second virtual channels generated by the second virtual channel generating means; Second virtual channel distribution means for analyzing second received data and distributing to the corresponding second virtual channel among the n second virtual channels generated by the second virtual channel generating means; And transmitting second received data received from the first communication means through the single physical channel to the second virtual channel distribution means, or transmitting data received from the second virtual channel merging means through the single physical channel. And second communication means for transmitting to the first communication means.

4. Important uses of the invention

The present invention is used for a composite terminal having two central processing units.

Description

Multiple access communication apparatus that extends one physical channel into multiple virtual channels {Serial line multiplexer interface apparatus}

The present invention relates to a communication device between two CPUs connected to a single physical channel. More particularly, the present invention relates to a plurality of virtual channels connected to a single physical channel connecting two CPUs. The present invention relates to a multi-access communication device capable of simultaneously providing desired functions, programs, and services through each virtual channel.

Hereinafter, a wireless communication module (CDMA module) and a PDA (Personal Digital Assistance) module will be described as two CPUs. However, it should be noted that the present invention is not limited to the communication between the wireless communication module and the PDA module.

Due to the demand of various functions for the PDA terminal and the rapid spread of the Internet, one of the important functions to be provided in the PDA terminal is the Internet access function through the wireless communication module (eg, CDMA module, GSM module, WLAN module, etc.). Voice call function. That is, the PDA terminal has been developed as a composite terminal in which the functions of the cellular phone and the Internet access function are combined with the existing PDA functions. Such a composite terminal should provide an environment capable of providing or implementing various functions using a wireless communication network as well as the existing personal information management function as well as internet access through a wireless communication module, voice call function, and short message transmission / reception function.

Indeed, between the wireless communication module and the PDA module, functions such as data communication, voice call control, short message service, and EIF must be simultaneously implemented and simultaneously serviced.

However, in current composite terminals, physical communication channels are generally limited to one, so it is very inconvenient to provide various functions or services at the same time. For example, in a PDA having a wireless communication module, there is a physical communication channel capable of exchanging data or information between the wireless communication module and the PDA module. However, this physical communication channel is usually limited to one, so that multiple programs or services cannot be used simultaneously. Therefore, this type of PDA terminal can provide only a limited number of physical communication channels (usually one) at the same time, but the limitation of the physical communication channel even if you want to provide more programs, services and functions. Due to this, only the number of physical communication channels can be provided.

Therefore, in the present composite terminal, if there is a request for another function or service while using one function or service, the new terminal ignores this new request or terminates the currently used function or service and provides a newly requested function or service. I'm using.

In addition, the above-described complex terminal is usually divided into a portion which handles a PDA function and a portion which handles a wireless communication function, and a function is provided by a separate central processing unit (CPU). That is, there are two central processing units to perform their respective functions, and there is a physical communication channel between the two central processing units, so that the data or information is exchanged between the two central processing units.

However, the number of physical communication channels is usually limited to one, and it is difficult to increase the number, such as the use of a separate semiconductor chip to expand the number, and also increase the manufacturing cost of the terminal. Therefore, a limited number of physical communication channels can be provided at the same time limited to the number of physical communication channels. As a result, it is difficult to make a composite terminal having high performance and quality.

As a result, a program or service operating in a PDA module or a wireless communication module exchanges a lot of data and information with a program or service of the other party. In this case, a physical communication channel is used to exchange data or information, but many communication channels cannot be shared due to the characteristics of the physical communication channel. In the case of using a physical communication channel that cannot be shared, the number of physical communication channels limits the number of programs or services to exchange data or information at the same time. For example, if there is only one physical communication channel, if the wireless Internet program occupies the physical communication channel, voice call control function or short message service cannot be used at the same time.

The present invention has been proposed to solve the above problems, and extends a single physical channel connecting two CPUs to a plurality of virtual channels to provide desired functions, programs, and services through each virtual channel. It is an object of the present invention to provide a multi-access communication device that can be provided simultaneously.

The apparatus according to the present invention for achieving the above object is, in a multiple access communication device in which one physical channel is extended to a plurality of virtual channels, n (n is a natural number) that can be used in the external central processing unit First virtual channel generating means for generating a first virtual channel; First virtual channel merging means for merging data received through the n first virtual channels generated by the first virtual channel generating means; First virtual channel distribution means for analyzing first received data and distributing the first received data to a corresponding first virtual channel among the n first virtual channels generated by the first virtual channel generating means; First communication means for transmitting first received data received through the single physical channel to the first virtual channel distribution means, or transmitting data received from the first virtual channel merging means through the single physical channel; Second virtual channel generating means for generating n second virtual channels usable by an external second central processing unit; Second virtual channel merging means for merging data received through the n second virtual channels generated by the second virtual channel generating means; Second virtual channel distribution means for analyzing second received data and distributing to the corresponding second virtual channel among the n second virtual channels generated by the second virtual channel generating means; And transmitting second received data received from the first communication means through the single physical channel to the second virtual channel distribution means, or transmitting data received from the second virtual channel merging means through the single physical channel. And second communication means for transmitting to the first communication means.

As described above, the present invention creates a plurality of virtual logical channels in a physical communication channel in a PDA terminal in which a wireless communication module is embedded, and simultaneously provides a desired number of programs, services, and functions to be provided through a communication channel in a PDA terminal. It is characterized in that it serves to function.

That is, the present invention provides a virtual logical channel (virtual channel) that can be theoretically extended to an infinite number of physical communication channels (physical channels) for communication between a wireless communication module and a PDA module in a PDA terminal having a wireless communication module. By implementing this, it is possible to efficiently use limited resources (physical channels) and to provide many functions and services at the same time.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an exemplary view for explaining a schematic configuration between a wireless communication module and a PDA (Personal Digital Assistance) module to which the present invention is applied, and is a wireless communication module 110, a single physical channel 120, and a PDA module. 130. The wireless communication module 110 includes a wireless communication module RF processing unit 111, a wireless communication module central processing unit 112, and a wireless communication module communication unit 113, and the PDA module 130 is a PDA module communication unit. 131, and a PDA module central processing unit 132.

Referring to FIG. 1, each of the above components is described in detail as follows.

First, the RF processing unit 111 of the wireless communication module is a part that processes radio wave transmission and reception with a base station, and processes according to the CDMA (CDMA 1x, CDAM 1x EVDO, cdma2000, etc.) or GSM (GPRS, UMTS, etc.) The radio frequency band may be different.

The wireless communication module central processing unit 112 is a part for processing and interpreting data or information collected from the outside, and is responsible for the function of the mobile telephone.

In addition, the wireless communication module communication unit 113 is a part that transmits and receives data to be exchanged with the PDA module 130, and collects data received from the PDA module 130 through the single physical channel 120 or the single physical channel 120. ) Transmits the data to the PDA module 130 through.

In addition, the single physical channel 120 is a physical communication channel for exchanging data or information between the wireless communication module 110 and the PDA module 130, and is a portion in which a direct electronic signal flows. In the present invention, a single physical channel is described as an example.

And, the PDA module communication unit 131 is a part for transmitting and receiving data to be exchanged with the wireless communication module 110, collecting data received from the wireless communication module 110 through a single physical channel 120 or a single physical channel ( It performs a function of transmitting data to the wireless communication module 110 through 120.

The PDA module central processing unit 132 processes and interprets data or information collected from the outside, and generally performs a function similar to a computer.

As such, the physical communication channels are configured in a very limited number, and in order to increase the physical communication channels, a separate semiconductor chip must be generally used. However, if a virtual logical channel is configured to extend one physical communication channel indefinitely, the communication channel can be easily expanded without using a separate component. A method of physically extending a single communication channel into n virtual logical channels (n is a natural number) will be described in detail with reference to FIG. 2.

2 is a block diagram of an embodiment of a multiple access communication apparatus for communicating by extending a single physical channel between a wireless communication module and a PDA module to a plurality of virtual channels according to the present invention. Wireless communication module virtual channel merging unit 202, wireless communication module virtual channel distribution unit 203, wireless communication module communication unit 204, single physical channel 205, PDA module communication unit 206, PDA module virtual channel merging unit 207, the PDA module virtual channel distribution unit 208, and the PDA module virtual channel generation unit 209.

The wireless communication module virtual channel generation unit 201 is a portion for generating and providing n virtual channels that can be used by the wireless communication module central processing unit 112 and the virtual n number that can communicate with the PDA module 130. It performs a function of making a communication channel to the wireless communication module (110).

In addition, the wireless communication module virtual channel merging unit 202 transmits data collected through the n virtual channels generated by the wireless communication module virtual channel generating unit 201 through one physical communication channel 205 to the PDA module. Merge data to transmit to the 130. At this time, the wireless communication module virtual channel merging unit 202 processes the data into a standardized communication message, and records virtual channel information on which virtual channel the data is input to the communication message (for example, in an address field, respectively). Record and transmit the virtual channel number so that the other party can use this information when interpreting and distributing the message.

In addition, the wireless communication module virtual channel distribution unit 203 analyzes data received from the PDA module 130 through a single physical communication channel 205 and generates the data in the wireless communication module virtual channel generation unit 201. It performs the function of distributing to the corresponding virtual channel among the n virtual channels. At this time, the wireless communication module virtual channel distribution unit 203 analyzes the virtual channel information (for example, the virtual channel number recorded in the address field) included in the communication message and distributes the data to the corresponding virtual channel.

The wireless communication module communication unit 204 transmits and receives data to be exchanged with the PDA module 130, and collects data received from the PDA module 130 through a single physical channel 205 to virtualize the wireless communication module. It transmits to the channel distribution unit 203, or transmits the data received from the wireless communication module virtual channel merger 202 to the PDA module 130 through a single physical channel (205).

The single physical channel 205 is a physical communication channel for physically connecting the wireless communication module 110 and the PDA module 130 to transfer data or information therebetween, and is a portion in which a direct electronic signal flows.

In addition, the PDA module communication unit 206 transmits and receives data to be exchanged with the wireless communication module 110. The PDA module virtual channel collects data received from the wireless communication module 110 through a single physical channel 205. It transmits to the distribution unit 208, or transmits the data received from the PDA module virtual channel merger 207 to the wireless communication module 110 through a single physical channel (205).

The PDA module virtual channel merger 207 transmits data collected through the n virtual channels generated by the PDA module virtual channel generator 209 through one physical communication channel 205 to the wireless communication module 110. Merge data to be sent to). At this time, the PDA module virtual channel merging unit 207 processes the data into a standardized communication message and records virtual channel information on which virtual channel the data is input to the communication message (for example, in each address field). By recording and transmitting the virtual channel number, the counterpart uses this information when interpreting and distributing the message.

And, the PDA module virtual channel distribution unit 208 analyzes the data received from the wireless communication module 110 through a single physical communication channel 205, n generated by the PDA module virtual channel generation unit 209 Performs a function of distributing to corresponding virtual channels among the virtual channels. At this time, the PDA module virtual channel distribution unit 208 analyzes the virtual channel information (for example, the virtual channel number recorded in the address field) included in the communication message and distributes the data to the corresponding virtual channel.

The PDA module virtual channel generator 209 generates and provides n virtual channels that can be used by the PDA module central processing unit 132. The PDA module virtual channel generator 209 generates virtual n communication channels for communicating with the wireless communication module. It performs a function to make the PDA module 130.

Next, an operation of extending a single physical channel to n virtual channels to communicate is as follows.

The program or service operating in the PDA module 130 or the wireless communication module 110 of the present invention opens a virtual channel provided by each when a communication channel is required to transmit and receive a lot of data and information with a program or service of the other party. Send and receive data.

First, when data is input through multiple virtual channels, the input data is processed into a formal communication message through a virtual channel merger. At this time, the virtual channel information about which virtual channel data is input is recorded in the communication message (for example, each virtual channel number is recorded in the address field) and transmitted. Use virtual channel information.

The data input through the multiple virtual channels are merged in the virtual channel merger and transferred to the communication unit. Then, the communication unit delivers the received communication message to the communication unit of the other party through a single physical communication channel.

Then, the communication unit of the opposite module delivers the received communication message to the virtual channel distribution unit. Then, the virtual channel distribution unit analyzes the virtual channel information (for example, the virtual channel number recorded in the address field) included in the received communication message and determines which virtual channel to transfer. When the virtual channel to be transmitted is identified and a message is sent, the receiving virtual channel receives this data and delivers the data from the counterpart to a program or service that wants to receive data from the other party.

For example, in the case of a hybrid PDA terminal having a wireless communication module having only one physical communication channel, when a wireless Internet program occupies a physical communication channel, voice call control function or short message service may be simultaneously used. It becomes impossible. However, this problem can be easily overcome by using a virtual channel logically expanded to a single physical communication channel. That is, it is possible to simultaneously send and receive a short message while performing an e-mail or web search through the wireless Internet, and to control voice calls at the same time.

As described above, the present invention uses a virtual channel in which a single physical communication channel is logically extended to n, so that a physically limited resource can be extended and used, and a hybrid PDA having high performance and quality easily and safely without additional cost or effort. Allows you to create a terminal.

Next, an example of specifically implementing the present invention as described above will be described.

In an exemplary embodiment of the present invention, a bit-oriented protocol is used as a data communication method. The bitwise protocol refers to a protocol of using a flag (01111110), which is a special bit string, without using a character having meaning in indicating the beginning and end of a frame constituting a message.

Representative protocol of this method is HDLC (High-Level Data Link Control) of International Organization for Standardization (ISO). The reason for this is to reduce the process of escape characters for special characters.

In relation to the communication control right, an Asynchronous Balanced Mode (ABM) is used. By using this, a command frame or a response frame can be transmitted and received without permission in the communication method between the CDMA module and the PDA module.

In addition, the HDLC interfaces used between the PDA module and the CDMA module remain intact, and as shown in FIG. 3, a virtual channel is applied to a DLC (Data Link Connect) portion of the PDA module and a DLC portion of the CDMA module. To add a new multiplexer layer (301).

Figure 4 is an exemplary view of the hardware of a multi-access communication device implemented in accordance with the present invention, using a Strong Arm 1110 processor as a PDA module, Qualcomm's MSN 5000 processor as a CDMA module, UART- as a communication line An example is shown using 232 lines.

5 is an exemplary view illustrating a software channel configuration of a multiple access communication apparatus implemented according to the present invention, in which a plurality of applications on a PDA module side are connected to a physical serial interface through a virtual channel, and a plurality of CDMA module sides are illustrated. Applications also show a structure that is connected to a physical serial interface through a virtual channel. This will be described later in more detail with reference to FIG. 7.

6 is a structural diagram of an embodiment of a transport packet according to the present invention.

As shown in Fig. 6, the flag fields (start flag and end flag) 601, 605 are used to synchronize a frame and have a unique pattern 10011111B. And all the frames start with the start flag 601 and end with the end flag 605. In the present invention, several transmission packets are sent in one transmission request.

Data start (Stx) field 602 indicates the start of data.

In addition, an address field 603 represents a number for each virtual channel. For example, when 1 byte is used, a total of 256 channels (2 ⁸ channels) can be displayed. Actually, special characters used for a packet (9FH (Start Flag), FCH (STX), 7DH ( Escape Character) and 252 (256-4) channels other than Channel 0 may be displayed.

The information field 604 is a part including data, and the data already includes an algorithm for error processing. Therefore, it is based on the data communication method between the conventional CDMA module and PDA module.

At this time, in order to distinguish the case where the character representing the data in the information field is 9FH or 7DH, which is a special symbol, an exception character processing is performed to change the corresponding data character to 9DH, 7FH, and 7DH to 7DH, 5DH. do.

7 is a diagram illustrating an embodiment of a layer of software according to a multiple access communication device implemented according to the present invention.

In the drawing, the serial driver 701 is a part corresponding to the PDA module communication unit 206 or the wireless communication module communication unit 204 of FIG. 2 and is represented as a software COM.

The multi-channel driver 702 wirelessly communicates with the software layer or the wireless communication module virtual channel distribution unit 203 including the PDA module virtual channel distribution unit 208 and the PDA module virtual channel merging unit 207 of FIG. 2. The software layer including the module virtual channel merger 202 is shown. This part 702 processes the serial event from the serial driver 701 and processes the packet received from the serial driver 701 to deliver to the virtual channel port 703. It receives the data to be transmitted from the application (APP) 704 through the virtual channel port 703 and processes the packet to deliver to the serial driver 701.

The virtual channel port 703 is a software layer corresponding to the PDA module virtual channel generator 209 or the wireless communication module virtual channel generator 201 of FIG. 2. The application 704 provides a substantial port service.

In addition, the application program 704 represents an application program using the virtual channel port (SMP Port) 703 in the PDA module or the wireless communication module. The existing programs do not use the COM port. Therefore, data is transmitted using an SMP (1 ... N) port composed of virtual channels.

8 is a flowchart illustrating an embodiment of a reception process of a multiple access communication apparatus implemented according to the present invention.

First, the SMP_COM event handler 801 processes an event received from a serial driver. If the event is RX, data is received from the serial driver, loaded into the SMP-COM receive queue 802, and notified to the channel distribution unit 803 that there is data received. For events other than RX, the application classifies whether the event is desired to be received and transmits the event to the corresponding application if the event is desired to be received.

When the channel distribution unit 803 is notified of the data reception from the SMP-COM event handler 801, the channel distribution unit reads data from the SMP-COM reception queue 802, analyzes the packetized data, and analyzes the virtual channel information. After storing in the corresponding SMP queue 804 according to the virtual channel number recorded in the field, the corresponding application is notified of data reception. At this time, it checks whether there is a special character code string in the received data and also serves to reduce the special character code string to the special character.

The SMP queue 804 is a queue that serves to temporarily receive data to be transmitted to an application program from the channel distribution unit 803 and exists one by one for each SMP port 703 of FIG. 7. In the form of data stored here, only pure data decomposed in a packet is stored.

Referring again to the overall flow, when the data driver is notified of the data reception, the SMP-COM event handler 801 stores the data received in the SMP-COM reception queue 802 and receives the data in the channel distribution unit 803. Inform. Then, the channel distribution unit 803 reads data from the SMP-COM reception queue 802, analyzes the packetized data, and stores the data in the corresponding SMP queue 804 according to the virtual channel number recorded in the address field. Later, the application is notified of receiving data. The application then receives data from the SMP queue 804.

9 is a flowchart illustrating a transmission process of a multiple access communication apparatus implemented according to the present invention.

First, the SMP-COM control handler 901 aggregates the signal processing requests from each application program and requests the serial driver to process signals indicating the current terminal state.

In addition, the channel merger 902 serves to packetize the data requesting transmission from the application program and transmit the packetized data to the serial driver. At this time, if a special character is included, it also plays a role of converting it to a special string. In addition, when multiple applications request data transmission at the same time, the channel merger 902 transmits all the data of multiple applications in one transmission request. At this time, synchronization is performed to prevent abnormal packets from being transmitted to the serial driver. Perform. In other words, the synchronization process delays requests from other applications while generating completed packets for several applications simultaneously. The channel merger 902 processes the packetization of another delayed request after writing and transmitting the data requested by the various applications as a packet.

The present invention as described above can be applied regardless of a CDMA (CDMA 1x, CDAM 1x EVDO, cdma2000, etc.) module using a serial interface or a GSM (GPRS, UMTS, etc.) module using a USB interface.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

The present invention as described above, by implementing a plurality of virtual logical channels in one physical communication channel for communication between the wireless communication module and the PDA module, by extending the physically limited communication channel and various functions and services for each virtual channel and Program can be provided.

As such, the present invention implements a plurality of virtual logical channels in one physical communication channel, so that a plurality of applications or services can share a single physical communication channel and process many functions at the same time. However, when a service occupies a physical channel, another program or service may not be able to operate. That is, by implementing a plurality of virtual channels in one physical communication channel, there is a big advantage that can provide a desired function at the same time by extending the number of virtual channels as necessary, regardless of which program or service should be provided at the same time.

This greatly improves the functionality and quality of PDAs with embedded wireless communication modules, and provides an effective sharing method for physically limited resources. It can increase.

1 is an exemplary view for explaining a schematic configuration between a wireless communication module and a PDA (Personal Digital Assistance) module to which the present invention is applied.

2 is a diagram illustrating an embodiment of a multi-access communication apparatus in which one physical channel (hereinafter, referred to as a "single physical channel") between a wireless communication module and a PDA module is expanded to communicate with a plurality of virtual channels.

3 is an exemplary diagram for a multiple access hierarchy in accordance with the present invention.

4 is an exemplary diagram of hardware of a multiple access communication apparatus implemented in accordance with the present invention.

5 is an exemplary view illustrating a software channel configuration of a multiple access communication apparatus implemented in accordance with the present invention.

6 is a structural diagram of an embodiment of a transport packet according to the present invention;

7 illustrates an embodiment of a layer of software in accordance with a multiple access communication device implemented in accordance with the present invention.

8 is a flowchart illustrating an embodiment of a reception process of a multiple access communication apparatus implemented in accordance with the present invention.

9 is a flowchart illustrating an embodiment of a transmission process of a multiple access communication apparatus implemented according to the present invention.

* Explanation of symbols for the main parts of the drawings

201: wireless communication module virtual channel generation unit 202: wireless communication module virtual channel merger

203: wireless communication module virtual channel distribution unit 204: wireless communication module communication unit

205: single physical channel 206: PDA module communication unit

207: PDA module virtual channel merger 208: PDA module virtual channel distributor

209: Virtual channel generator of PDA module

Claims (11)

In a multiple access communication apparatus in which one physical channel (hereinafter referred to as "a single physical channel") is extended to a plurality of virtual channels, First virtual channel generating means for generating n first virtual channels usable by an external first central processing unit (n is a natural number); First virtual channel merging means for merging data received through the n first virtual channels generated by the first virtual channel generating means; First virtual channel distribution means for analyzing first received data and distributing the first received data to a corresponding first virtual channel among the n first virtual channels generated by the first virtual channel generating means; First communication means for transmitting first received data received through the single physical channel to the first virtual channel distribution means, or transmitting data received from the first virtual channel merging means through the single physical channel; Second virtual channel generating means for generating n second virtual channels usable by an external second central processing unit; Second virtual channel merging means for merging data received through the n second virtual channels generated by the second virtual channel generating means; Second virtual channel distribution means for analyzing second received data and distributing to the corresponding second virtual channel among the n second virtual channels generated by the second virtual channel generating means; And The second received data received from the first communication means through the single physical channel is transferred to the second virtual channel distribution means, or the data received from the second virtual channel merging means is transmitted through the single physical channel. Second communication means for transmitting to the first communication means Multi-access communication device that extends one physical channel including a plurality of virtual channels. The method of claim 1, The virtual channel merging means, Multi-access that extends one physical channel to a plurality of virtual channels while packetizing data into a communication message, recording and transmitting virtual channel information on which virtual channel has been input to the communication message. Communication device. The method of claim 2, The virtual channel distribution means, And a physical channel extended to a plurality of virtual channels, wherein the virtual channel information included in the communication message is interpreted to distribute data to the corresponding virtual channel. The method of claim 2 or 3, The virtual channel information, A multiple access communication device in which one physical channel is extended to a plurality of virtual channels, wherein each virtual channel number is recorded in an address field. The method according to any one of claims 1 to 3, The virtual channel distribution means, An event handler for processing an event received from the corresponding communication means; A reception queue for storing data received from said communication means; A channel distribution unit for notifying the reception of data from the event handler, reading the data from the reception queue, analyzing the packetized data, delivering the packetized data to the corresponding queue according to the virtual channel information, and notifying the corresponding application of the data reception; And N queues for receiving data from the channel distribution unit and temporarily storing the data and transmitting the data to the application program Multi-access communication device that extends one physical channel including a plurality of virtual channels. The method of claim 5, wherein The channel distribution unit, And checking a special character code string in the data read from the reception queue to reduce the special character code string to a special character. The method of claim 5, wherein The virtual channel merging means, A control handler which aggregates signal processing requests from respective applications and requests signal processing to the corresponding communication means; And Channel merging unit for packetizing the data request for transmission in each application program and delivering to the corresponding communication means Multi-access communication device that extends one physical channel including a plurality of virtual channels. The method of claim 7, wherein The channel merging unit, A multi-access communication device in which one physical channel is extended to a plurality of virtual channels, characterized in that the data is converted to a special string if the special character is included in the data. The method of claim 7, wherein The channel merging unit, If several applications want to send data at the same time, while creating a completed packet for the application, while delaying a request from other applications, the application writes the data requested by the various applications in a packet and sends it to another delayed request. Multi-access communication device that extends one physical channel to a plurality of virtual channels, characterized in that for processing the packetization. The method according to any one of claims 1 to 3, The multiple access communication device, A multi-access communication device in which one physical channel is extended to a plurality of virtual channels, wherein the CDMA module and the PDA module are connected by using a serial interface. The method according to any one of claims 1 to 3, The multiple access communication device, Multi-access communication device that extends one physical channel into a plurality of virtual channels, characterized in that the GSM module and the PDA module using a USB interface.