JP4885810B2 - Wireless terminal adapter - Google Patents

Description

  The present invention is an adapter for a wireless terminal that is used in a packet communication network of a mobile phone and that allows Ethernet (registered trademark) external devices to be connected to any of different virtual closed networks set for each access point. About.

  2. Description of the Related Art Conventionally, a dial-up router is known as a device that performs Ethernet (parallel) -serial conversion for conversion between Ethernet-side communication and Internet-side serial communication in a packet communication network of a cellular phone.

  This dial-up router has a function of connecting to an Internet provider and a function of connecting to an external device on the Ethernet side (hereinafter referred to as an Ethernet external device), and the IP (Internet Protocol: Internet Protocol) from the Ethernet external device. ) Packet (IP packet) as a trigger and is dialed to the modem, and is set in advance in one place such as an Internet provider, triggered by reception of IP packets from a plurality of Ethernet external devices. The access point (AP: Access Point) which is the connection destination telephone number is dialed and connected there. That is, the dial-up router connects the Ethernet and the Internet via a telephone line when dialed to an Internet provider AP with an Ethernet external device.

  The dial-up router also converts a global IP address and a local IP address (NAT (Network Address Translation) function) and TCP / UDP (Transmission Control Protocol / User Datagram Protocol). Port number, and a function of converting between a global IP address and a local IP address (IP masquerade function). Such a dial-up router is characterized in that a plurality of Ethernet external devices can communicate with a server in the same access point with one global IP address.

  By the way, in order to ensure security, a packet communication network of a mobile phone is often operated on a network called IP-VPN (IP Virtual Private Network). This is to improve security by providing a virtual closed network for each access point and restricting access from one virtual closed network to another virtual closed network (Non-Patent Documents 1 to 6 and Patent Documents). 1).

  FIG. 9 is a system conceptual diagram showing a configuration example of a conventional packet communication network in which IP-VPN is set.

  In the figure, here, a packet communication network in which access points are respectively set in two communication companies is assumed. In this packet communication network, communication is established between the device a and the server α, and the device b And the server β are configured to establish communication. Each of the devices a and b is a wireless communication apparatus having an Ethernet external device (not shown), and an access point A is set for the communication company of the server α, and an access point B is set for the communication company of the server β. Yes.

  Here, in order to ensure the security between the communication between the device a and the server α and the communication between the device b and the server β, the virtual closed network A for the access point A and the virtual for the access point B are virtual. Each closed network B is set. It is assumed that the virtual closed network A includes a server α and the virtual closed network B includes a server β. The virtual closed networks A and B are independent from each other, and access between them is prohibited.

  In such a packet communication network, each of the devices a and b is provided with the dial-up router, so that each of the devices a and b can connect to only one access point. Here, assuming that device a is set to be connectable to access point A and device b is set to be connectable to access point B, communication is performed between device a and server α. In this case, by dialing the access point A from the device a, the server α can be accessed via the virtual closed network A (ie, dialed), and between the device a and the server α. Communication is possible. When communication is performed between the device b and the server β, the server β can be accessed via the virtual closed network B by dialing the access point B from the device b (that is, dialing). Connected) to enable communication between device b and server β. However, even if the access point B is dialed by the device a, the server β cannot be accessed, and communication between the Ethernet external device a and the server β cannot be performed. Similarly, even if the access point A is dialed by the device b, the server α cannot be accessed, and communication between the Ethernet external device b and the server α cannot be performed.

In this way, by restricting access to the server for each device, it is possible to ensure security between the communication networks between the device and the server.
`` 3GPP TS27.005 Use of Data Terminal Equipment-Data Circuit terminating Equipment (DTE-DCE) interface for Short Message Service (SMS) and Cell Broadcast Service (CBS), Release-7 '', 3GPP (3rd Generation Partnership Project), 2007 June 7, `` 3GPP TS27.007 AT command set for User Equipment (UE), Release-7 '', 3GPP, June 7, 2007 3GPP TS27.010 Terminal Equipment to User Equipment (TE-UE) multiplexer protocol, Release-7, 3GPP, June 7, 2007 "3GPP TS27.060 Packet domain; Mobile Station (MS) supporting Packet Switched service, Release-7", 3GPP, June 7, 2007 "3GPP TS27.901 Report on Terminal Interface-An Overview, Release-7", 3GPP, June 7, 2007 "FOMA Ubiquitous Module FOMA UM01-KO Instruction Manual", [online], January 2007, NTT DOCOMO Group, "July 27, 2007 search", Internet <URL: http: //www.docomo. biz / img / module / pdf / foma_manual.pdf> JP 2006-146895 A

  By the way, according to the packet communication network as described above, each device obtains an IP packet from an Ethernet external device by the dial-up router and requests connection with a server to cope with this and connect (access) Only one access point set in advance can be used. However, in some systems, it is desirable that one device can access any of a plurality of access points.

  For example, in recent years, various types of cards have been issued, and a card system has been realized in which different services can be provided for each type of card. In such a card system, a different terminal such as a card reader is used for each type of card, and the terminal is used to communicate with the card issuing company using the packet communication network shown in FIG. .

  That is, the device a is provided with a type a card (card a) terminal as an Ethernet external device, and the device b is provided with a type b card (card b) as an Ethernet external device. The server α is a server of the issuing company of the card a, and the server β is a server of the issuing company of the card b. When using the card a, the access point of the issuing company of the card a is dialed using the terminal of the device a so that the device a is connected to the server α, and when the card β is used, The access point of the issuing company of the card b is dialed using the terminal of the device b, and the device b is connected to the server β.

  Thus, when using each card, it is necessary to access the corresponding access point using the device corresponding to the type of the card, and when using the card a, the device not corresponding to the type Even if b is used or a device b that does not correspond to the type of card b is used, the corresponding access point cannot be accessed and the card cannot be used.

  However, there are many types of cards, and it is very inconvenient that a user who owns a plurality of types of cards uses a different device, that is, a terminal, for each type of card to be used. It is desirable to be able to use each type of card in any device. As a method for solving this, in FIG. 9, virtual closed networks A and B can be interconnected to enable access between them (tunneling between virtual closed networks). Independence is often lost and security is often a problem.

  An object of the present invention is to provide an adapter for a wireless terminal capable of solving such a problem and securing one or more desired access points from any device while ensuring security. .

  In order to achieve the above object, the present invention is an adapter for a wireless terminal of a device connected to an access point in which a virtual closed network is set, and a plurality of Ethernet external devices with different access points can be connected. A table showing correspondence between the IP address of the Ethernet external device and the access point name of the access point to be connected is provided, and the access point name of the IP address of the Ethernet external device that requests connection is specified based on this table, Based on the specified access point name, connection with the corresponding access point is performed.

  According to the present invention, it is possible to connect to any of access points of different virtual closed networks, and it is possible to receive provision of different services on the same device.

  FIG. 8 is a diagram showing a concept of a packet communication network using a wireless terminal adapter according to the present invention, and parts corresponding to those in FIG.

  In the figure, each of the devices a and b is equipped with a wireless terminal adapter according to the present invention. For example, as in the device a, it is possible to access one access point A, but as in the device b. In addition, different access points A and B can be accessed. Therefore, taking the card system as an example, the device a can use only one type of card, but the device b has a card communicating with the access point A (card issuing company A) and an access point B (card A card of a different type from the card that communicates with the issuing company B) can be used.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a system conceptual diagram showing the concept of an IP packet communication network using a wireless terminal adapter according to the present invention, where 1 is a wireless terminal adapter according to the present invention, 2 is a wireless terminal, 3 is a device, Ethernet external devices, 5 is a base station, 6 is a packet network, and 7 is a server.

  In the figure, a wireless terminal adapter 1 having a router function and a wireless terminal 2 constitute a device 3 corresponding to the devices a and b in FIG. 9, and a WAN (Wide Area Network) such as RS-232C. A wide area information communication network) is connected to enable serial communication. For example, a terminal such as a card reader is connected to the device 3 as an Ethernet external device 4 via an Ethernet interface via an Ethernet cable.

  A packet network 6 having the functions of virtual closed networks A and B shown in FIG. 9 is connected to a base station 5 that performs wireless communication with the wireless terminal 2 of the device 3, and a server 7 is connected thereto. . One access point A is set in the packet network 6.

  When there is a dial to the access point A in the Ethernet external device 4, a local IP address is supplied from the Ethernet external device 4 to the wireless terminal adapter 1 via the Ethernet cable, and an access point name that designates the access point A It is converted into a global IP address (APN: Access Point Name), and further Ethernet (parallel) -serial conversion is performed and serial communication is performed with the wireless terminal 2. In the wireless terminal 2, the access point name, which is a global IP address, is transmitted to the base station 5 of the IP packet communication network after predetermined processing for transmission is performed.

  The access point name received by the base station 5 is supplied to the packet network 6 after receiving processing and is confirmed whether or not this access point name designates the access point A, and designates this. If not, the access point name is discarded. If the access point name is designated, a communication network between the Ethernet external device 4 and the server 7 is established.

  When such communication is established, a notification IP packet to that effect is transmitted from the packet network 6 to the device 3 via the base station 5 together with the access point name of the access point A and the global IP address for the device 3. The In the device 3, the notification is received by the wireless terminal 2, received processing is performed, and serial communication is performed with the wireless terminal adapter 1. The wireless terminal adapter 1 serial-to-Ethernet (parallel) conversion of the notification IP packet and the global IP address, and also converts the global IP address into a local IP address for the Ethernet external device 4, Supply to device 4.

  Upon acquiring this notification, the Ethernet external device 4 outputs an IP packet to the wireless terminal adapter 1 and transmits it to the packet network 6 of the access point A via the established communication network.

  Here, the wireless terminal adapter 1 stores a table (association table) indicating the correspondence between the access point name and the IP packet, and by using this, conversion from the IP packet to the access point name and the access point are performed. Conversion from name to IP address is performed.

  2 is a block diagram showing a hardware configuration of an embodiment of the wireless terminal adapter 1 constituting the IP packet communication network shown in FIG. 1, wherein 8 is a control unit, and 9 and 10 are input / output units. , 11 is a ROM, and 12 is a RAM.

  In the figure, a wireless terminal adapter 1 is connected to an Ethernet external device 4 through an input / output unit 9 which is an Ethernet interface, and is connected to a wireless terminal through an input / output unit 10 which is a serial interface.

  The IP address by dialing from the Ethernet 4 is input by the input / output unit 9 and supplied to the control unit 8. In the control unit 8, the execution program stored in the ROM 11 is executed, and the above-mentioned association table stored in the RAM 12 is used, so that the IP address from the Ethernet external device 4 is the access point of the predetermined access point A. It is converted into a name, and further Ethernet (parallel) -serial converted and supplied to the input / output unit 10, serially communicated to the wireless terminal 2, and transmitted to the access point A.

  The access point name from the access point A received by the wireless terminal 2 and supplied by serial communication is input from the input / output unit 10, supplied to the control unit 8, and converted into the IP address of the Ethernet external device 4. Further, serial-Ethernet (parallel) conversion is performed, and the data is supplied to the input / output unit 9 and supplied to the Ethernet external device 4.

  In this manner, the wireless terminal adapter 1 converts the IP address of the Ethernet external device 4 into the access point name of the corresponding access point A using the association table, so that the access point name becomes the corresponding access point. Is established so that communication with this access point A is possible, and the access point name from this access point A is converted to the IP address of the corresponding Ethernet external device 4 As a result, the IP address is sent to the Ethernet external device 4.

  Incidentally, FIG. 1 shows a case where one Ethernet external device 4 is connected to one device 3, but in the present invention, by connecting a plurality of Ethernet external devices, different Ethernet external devices are connected. Communication with the access point can be established.

3 is a system configuration diagram showing a packet communication network when a plurality of Ethernet external devices are connected to the wireless terminal adapter 1 according to the present invention, where 4 ₁ , 4 ₂ ,..., 4 _n are Ethernet external devices. , 13 are hubs, and parts corresponding to those in FIG.

In the figure, the wireless terminal adapter 1 of the device 3 is connected to n (where n is an integer of 2 or more) Ethernet external devices 4 ₁ , 4 _{2 ,.} Is connected. These Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n are, for example, card readers, which are housed in one housing, and each housing is provided with one card reading unit. The type of card can be read by this card reader. The read card information is processed by the Ethernet external device 4 ₁ , 4 ₂ ,..., Or 4 _n corresponding to the type of the card, and is transferred from the hub 13 to the wireless terminal adapter 1 via the Ethernet cable 14. Supplied. These Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n are assigned to access points different from each other, and for this reason, these Ethernet external devices 4 ₁ , 4 _{2 ,.} The wireless terminal adapter 1 stores an associative table indicating the correspondence between the IP address of the access point and the access point name of the corresponding access point.

  FIG. 4 is a diagram showing a specific example of such an association table, in which 14 is a CID (context ID), 15 is an access point name (APN), 16 is an IP address, and 17 is related information of an Ethernet external device.

In this figure, this association table includes a CID (Context ID) 14 assigned to an access point, an access point name 16 of the access point, an IP address 17 assigned to the Ethernet external device, and related information 18 of the Ethernet external device. are those shown in association with, for example, when an Ethernet external device 4 _first IP address is the "192.168.1.2", the Ethernet external device 4 ₁ is a global IP address in the CID "1", "aaa.abc .ne.jp access point name of "(APN) is accessible to the access point a which is assigned, the IP address of the Ethernet external device 4 ₂ is" 192.168.1.3 ", the Ethernet external device 4 ₂ CID Is an access point for “bbb.abc.ne.jp”, the global IP address of Tonemu (APN) is that it is accessible to the access point B assigned.

Therefore, now, when the Ethernet external device 4 ₁ IP address "192.168.1.2" is supplied to the adapter 1 wireless terminals, the adapter 1 radio terminal, on the basis of this association table, the IP address "192.168. 1.2 ”is converted into the access point name“ aaa.abc.ne.jp ”which is the global IP address of access point A, and further, Ethernet (parallel) -serial conversion is performed to serially communicate with the wireless terminal 2. Is transmitted to the access point A. And, thereby, the communication path is established between the Ethernet external device 4 ₁ and the access point A. Similarly, when the Ethernet external device 4 ₂ IP address "192.168.1.3" is supplied to the adapter 1 wireless terminals, the adapter 1 radio terminal, on the basis of this association table, the IP address "192.168. 1.3 ”is converted into the access point name“ bbb.abc.ne.jp ”which is the global IP address of access point B, and further, Ethernet (parallel) -serial conversion is performed to serially communicate with the wireless terminal 2. Is transmitted to the access point B. And, thereby, the communication path is established between the Ethernet external device 4 ₂ and the access point B.

Further, when the access point name “aaa.abc.ne.jp” received from the access point A received by the wireless terminal 2 is serially communicated to the wireless terminal adapter 1 (in this case, the global designating the device 3). In the wireless terminal adapter 1, the access point name “aaa.abc.ne.jp” is converted from serial to Ethernet (parallel) and is shown in FIG. Based on the association table, this access point name “aaa.abc.ne.jp” is converted to the corresponding local IP address “192.168.1.2” and output to the hub 13. Thus, the IP address "192.168.1.2" is sent to the Ethernet external device 4 ₁ corresponding thereto. Similarly, when the access point name “bbb.abc.ne.jp” received from the access point B received by the wireless terminal 2 is serially communicated to the wireless terminal adapter 1 (in this case, the device 3 is designated). In addition, the wireless terminal adapter 1 converts the access point name “bbb.abc.ne.jp” into serial-Ethernet (parallel) and converts it into FIG. The access point name “bbb.abc.ne.jp” is converted into the corresponding local IP address “192.168.1.3” based on the association table shown in FIG. Thus, the IP address "192.168.1.3" is sent to the Ethernet external device 4 ₂ corresponding thereto.

  In this way, a plurality of access points can be accessed from one device 3, and for example, in a card system, a plurality of types of cards can be used using the same card reader. .

FIG. 5 is a diagram showing a protocol stack in the wireless terminal 2, the wireless terminal adapter 1, and the Ethernet external device 4 shown in FIG. 3, wherein 19 is a LAN (Local Area Network), 20 is a WAN (Wide Area Network). ), And parts corresponding to those in FIG. The Ethernet external device 4 represents _one of the Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n in FIG.

  In the figure, in the Ethernet external device 4, for example, when an application such as data is input by reading a card, the application is adapted to a communication protocol such as TCP (Transmission Control Protocol) or UDP (User Datagram Protocol). The IP packet is processed (IP packetized), and the MAC (Media Access Control address) address assigned to the Ethernet external device 4 is converted to the destination IP address (192.168.) Based on the ARP (Address Resolution Protocol) table. 1.1) and added to the IP packet.

  First, in order to establish communication with the corresponding access point, the IP address is output under the control of the Ethernet controller, and the 10BASE-T including the Ethernet cable 14 (FIG. 3) is included. The data is transmitted to the wireless terminal adapter 1 through the LAN 19 of / 100BASE1TX.

  The wireless terminal adapter 1 transmits / receives an IP packet including an IP address to / from the Ethernet external device 4, and transmits / receives an access point name and an IP packet to / from the wireless terminal 2. Thus, the IP address is converted. First, when the first IP address from the Ethernet external device 4 is received, an operation for connecting to the corresponding access point of the access destination of the Ethernet external device 4 is performed using the IP address. When the connection is completed, the IP packet in which the source IP address is converted is transmitted to the access point of the access point name (APN) corresponding to the source IP address (192.168.1.2) before the conversion.

  FIG. 6 is a flowchart showing the operation of the wireless terminal adapter 1 when an IP packet is received from the Ethernet external device 4, and this operation of the wireless terminal adapter 1 shown in FIG. 5 will be described below with reference to FIG. To do.

  When the wireless terminal adapter 1 receives an IP packet from the Ethernet external device 4 under the control of the Ethernet controller (step 100), the wireless terminal adapter 1 uses the ICMP (Internet Control Message Protocol) protocol. The status with the Ethernet external device 4 is confirmed using the source IP address of the received IP packet. If it is confirmed that this state is not normal, the received IP packet is discarded and the Ethernet external device 4 is requested to transmit the same IP packet again.

  If it is confirmed that this state is normal, it is confirmed whether or not the source IP address of the received IP packet is registered in the association table as shown in FIG. If it is not registered in the association table (“No” in step 101), the received IP packet is discarded together with its IP address (step 107).

  If it is confirmed that the source IP address of the received IP packet is registered in the association table (“Yes” in step 107), whether or not this IP address is the first supplied IP address That is, whether or not communication has already been established with the address point corresponding to this IP address, that is, whether or not a PPP connection capable of transmitting an IP packet to the corresponding access point according to PPP (Point to Point Protocol) is made. Is inquired of UART (Universal Asynchronous Receiver Transmitter) (step 102).

  When the IP address of the received IP packet is the first supplied IP address of the same address, that is, when the PPP connection is not established for this IP packet (“No” in step 102), The wireless terminal adapter 1 executes call control (Call Control) for calling the access point to the access point name (APN) of the access point corresponding to the source IP address of the received IP packet.

  This call control (Call Controll) converts an IP address into an access point name (APN) or CID of the corresponding access point using an association table as shown in FIG. Are transmitted to the UART and serially communicated with the wireless terminal 2 via the RS-232C WAN 20 (step 103). As a result, when a call is made and the response is confirmed, the access point name (APN) and information for authentication are transmitted according to the PPP protocol, and the connection with the corresponding access point ( It is confirmed whether or not (PPP connection) has been established (step 104).

  When the PPP connection is established (“Yes” in step 104), communication with the corresponding access point via the wireless terminal 2 is established, and the Ethernet external device 4 and the corresponding access point are established. (Step 106). In this way, when the PPP connection is established, for example, information (for example, a flag) indicating that fact is attached to a corresponding column (not shown) of the association table shown in FIG. 4 and the confirmation is made such that the PPP connection is released. Information indicating the result is stored.

  The wireless terminal 2 receives the access point name (APN) from the wireless terminal adapter 1 by UART and transmits it to the corresponding access point, but functions to bridge the corresponding access point using the PPP protocol ( PPP Bridge). Accordingly, from the wireless terminal adapter 1 to the access point name (APN), an IP packet that is just NAT-converted by the PPP protocol is transmitted from the wireless terminal 2 as it is.

  On the other hand, when the wireless terminal adapter 1 receives an IP packet whose source IP address is registered in the associative table as described above from the LAN 19, the PPP connection is made based on the information of the confirmation result. Is confirmed (“Yes” in step 102), it is determined whether or not the source IP address is an address having the accent point currently connected by PPP as the connection destination. When the IP address is different from the destination (“No” at step 105), the received IP packet is discarded (step 107). When the IP address is the same as the destination (“Yes” at step 105), Address conversion processing (NAT) for transmitting the received IP packet to the corresponding access point during PPP connection The (step 106).

The IP addresses assigned to the different Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n shown in FIG. 3 are different, and the association table shown in FIG. An access point name (APN) is associated. Therefore, when a plurality of Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n are connected to one wireless terminal adapter 1, access point name (APN) access corresponding to the Ethernet external device is performed. Communication with the point is established, and communication from one device 3 (FIG. 3) to a plurality of access points can be established. From this, for example, in the case of a card communication system, as shown in FIG. 8, different types of cards can be used in one device.

  FIG. 7 is a flowchart showing the operation of the wireless terminal adapter 1 when the wireless terminal 2 IP packet is received in FIG. 5. Hereinafter, the wireless terminal adapter 1 shown in FIG. The operation will be described.

  In the figure, when the wireless terminal adapter 1 receives an IP packet together with an access point name (APN) from an access point by UART (step 200), it converts them into serial-Ethernet (parallel), and the access point name. It is determined whether (APN) is registered in the association table as shown in FIG. 4 (step 201). If it is not registered (“No” in step 201), the received IP packet is discarded (step 207).

  When the received access point name (APN) is registered in the association table as shown in FIG. 4 (“Yes” in step 201), this access point name (APN) is also stored in this association table. Then, the IP address of the corresponding Ethernet external device 4 is converted and it is determined whether or not the wireless terminal adapter 1 is in a PPP connection state with this access point (step 202).

  If the wireless terminal adapter 1 is not connected to any access point by PPP (“No” in step 202), establishment of a new PPP connection is started (step 203), and a response is received from the access point. If there is, the connection process ends and the connection with the Ethernet external device 4 is completed (step 204). Thereafter, the IP packet received from the access point is transferred to the corresponding Ethernet external device 4 via the LAN 19 using the IP address converted from the access point name (APN) as a new destination address. As a result, the IP packet transmitted from the access point can be received by the corresponding Ethernet external device 4. In addition, when a PPP connection is established in this way, for example, information (for example, a flag) indicating that fact is attached to a corresponding column (not shown) of the association table shown in FIG. 4, and the PPP connection is released. Information indicating the confirmation result is stored.

  On the other hand, when the wireless terminal adapter 1 receives an IP packet in which the IP address converted from the access point name (APN) is registered in the association table as described above, the information on the confirmation result is received. Originally, when the connection with the corresponding Ethernet external device 4 is confirmed (“Yes” in step 202), whether or not the IP address is an address with the currently connected Ethernet external device 4 as the connection destination. If the IP address is different from the connection destination (“No” in step 205), the received IP packet is discarded (step 207), but if the IP address is the same as the connection destination (step 207). 205 “Yes”), control for transmitting the received IP packet to the Ethernet external device 4 of the connection destination Processing (Data Bridge) is performed (step 206). As a result, the IP packet sent from the access point is sent to the corresponding Ethernet external device 4, and the IP packet can be communicated between the access point and the Ethernet external device 4. Become.

As a result, in FIG. 8, the IP packet transmitted from the access point A to the device b corresponds to the corresponding one of the Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n shown in FIG. IP packets transmitted from the access point B to the device b are received by the Ethernet external devices 4 ₁ , 4 ₂ ,..., 4 _n shown in FIG. Is received by another corresponding Ethernet external device.

It is a system conceptual diagram which shows the concept of the IP packet communication network using the adapter for radio | wireless terminals by this invention. It is a block diagram which shows the hardware constitutions of one Embodiment of the adapter for wireless terminals by this invention which comprises the IP packet communication network shown in FIG. 1 is a system configuration diagram showing a packet communication network when a plurality of Ethernet external devices are connected to a wireless terminal adapter according to the present invention. FIG. It is a figure which shows one specific example of the association table set to the adapter for wireless terminals in FIG. It is a figure which shows the protocol stack in the radio | wireless terminal shown in FIG. 3, the adapter for radio | wireless terminals, and an Ethernet external device. 6 is a flowchart showing the operation of the wireless terminal adapter when an IP packet is received from the Ethernet external device in FIG. 5. 6 is a flowchart illustrating an operation of a wireless terminal adapter when an IP packet is received from the wireless terminal in FIG. 5. It is a system conceptual diagram which shows the structural example of the packet communication network using the adapter for radio | wireless terminals by this invention. It is a system conceptual diagram which shows the structural example of the conventional packet communication network in which IP-VPN was set.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Adapter for wireless terminals 2 Wireless terminal 3 Device 4 Ethernet external device 5 Base station 6 Packet network 7 Server 8 Control part 9,10 Input / output part 11 ROM
12 RAM
4 ₁ , 4 ₂ ,..., 4 _n Ethernet external device 13 Hub 14 CID
15 Access Point Name 16 IP Address 17 Ethernet External Device Related Information 19 LAN
20 WAN

Claims (1)

A wireless terminal adapter for a device connected to an access point with a virtual closed network,
Multiple Ethernet external devices with different access points can be connected,
A table indicating correspondence between the IP address of the Ethernet external device and the access point name of the access point to be connected is provided;
An access point name of an IP address of the Ethernet external device that requests connection is specified based on the table, and a connection with the corresponding access point is performed based on the specified access point name. Wireless terminal adapter.

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