JP2003046567A - Multi-tunnel gateway, virtual multi-drop access communication system and communication method in the system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To set a plurality of virtual tunnels for transferring a frame with a non-conventional communication protocol on a conventional network which adopts conventional network protocols. SOLUTION: A communication processing section 13 of a gateway 13-i transmits/receives a frame with a non-conventional communication protocol via a physical port. A capsulating/decapsulating processing section 132 capsulates the frame received by the communication processing section processing section 131 via the physical port in a way of transferring the frame via a virtual tunnel, designated by tunnel information registered in a gateway table 15-i . A communication processing section 135 transmits the capsulated frame to a connection destination gateway 13-j (#j) via a virtual tunnel on a conventional network 14 designated by the tunnel information. The gateway 13-j (#j) decapsulates the frame received via the virtual tunnel and transmits the resulting frame to a non-conventional communication protocol device from the physical port.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-tunnel gateway device for encapsulating and tunneling a frame of a non-general-purpose communication protocol in a general-purpose network constructed by a general-purpose network protocol technique, and particularly applies the non-general-purpose communication protocol. The present invention relates to a multi-tunnel gateway device, a virtual multi-drop connection communication system, and a communication method in the system, which are suitable for multi-drop connection between a host computer and a plurality of terminals to which a non-general communication protocol is applied on a general-purpose network.

[0002]

2. Description of the Related Art An automatic teller machine (ATM) and a cash dispenser (C), which are conventionally used in financial institutions.
The communication protocol of D) and the terminal for business use is generally in accordance with the original communication specifications of the general-purpose host computer maker. Therefore, this type of terminal is a general-purpose network as a communication infrastructure constructed by applying a general-purpose network protocol technology, such as the Internet or Internet protocol technology, that is, TCP (Tr
ansmission Control Protocol / IP (InternetProto
col) technology cannot be connected to and housed on the Internet.

Therefore, conventionally, in order to connect a host computer and a terminal to which a unique communication protocol conforming to the unique communication specifications of a general-purpose host computer maker, that is, a non-general-purpose communication protocol, is connected via a general-purpose network (Internet), It is common to use a gateway device to which a technique of encapsulating a frame of a non-general-purpose communication protocol (non-Internet protocol) and tunneling is applied, that is, a so-called tunnel gateway device. In this case, the connection configuration between the host computer and the terminal via the tunnel gateway device is a point-to-point connection.

[0004]

As described above, in the prior art, the host computer and the terminal (host terminal) that apply the communication protocol (non-general-purpose communication protocol, non-Internet protocol) unique to the general-purpose host computer are connected to the general-purpose network ( Use a tunnel gateway device to connect via Internet)
It was necessary to have a point-to-point connection configuration.

Therefore, in the prior art, a multi-drop connection configuration, which is often used as a multiplexing technique in the communication specifications of general-purpose host computer manufacturers, that is, as shown in FIG. 13, one host computer D1 and n computers, for example, It is impossible to use the multi-drop connection technology that realizes one-to-n (n = 2 in the figure) communication by connecting two terminals D12 and D13 by a shunt (multiplexing device) D4 that splits the physical signal. There was a problem.

The present invention has been made in consideration of the above circumstances, and an object thereof is to set a plurality of virtual tunnels for encapsulating and transferring a frame of a non-general-purpose communication protocol on a general-purpose network to which a general-purpose network protocol is applied. Therefore, a multi-tunnel gateway device and virtual multi-drop connection communication in which a host computer to which a non-general-purpose communication protocol is applied and a plurality of terminals to which a non-general-purpose communication protocol is applied can be virtually multi-drop connected via a general-purpose network. It is to provide a system and a communication method in the system.

[0007]

A multi-tunnel gateway device according to one aspect of the present invention is a non-general-purpose communication protocol via a physical port for connecting to a non-general-purpose communication protocol device to which the non-general-purpose communication protocol is applied. Communication processing means for transmitting and receiving a frame of the general-purpose network protocol and a second communication processing means for transmitting and receiving a frame of the general-purpose network protocol through a connection port of the general-purpose network to which the general-purpose network protocol is applied, and a non-general-purpose communication protocol Is a virtual tunnel used for encapsulating the frame and forwarding it through the general-purpose network, and tunnel information for designating a virtual tunnel set between the own gateway device and another gateway device is included. Registered tunnel information storage means, and the first
The encapsulation process for encapsulating the frame received by the communication processing means so that the frame can be transferred through the virtual tunnel specified by the tunnel information registered in the tunnel information storage means; Decapsulation processing for decapsulating the frame transferred via the virtual tunnel designated by the registered tunnel information and received by the second communication means, and encapsulation / decapsulation means. It is characterized by

In the multi-tunnel gateway device having such a configuration, for example, virtual tunnels are set between the other multi-tunnel gateway devices via the general-purpose network, and non-virtual tunnels received at the physical port are set. By encapsulating the transmission frame from the general-purpose communication protocol device, it becomes possible to transfer the encapsulated frame to another gateway device via the virtual tunnel. Further, a frame transferred from another gateway device to the own gateway device through the virtual tunnel and received at the connection port with the general-purpose network, that is, an encapsulated frame, is decapsulated and decapsulated from the physical port. It is transmitted to the general-purpose communication protocol device.

As described above, the multi-tunnel
The gateway device can realize a multi-tunnel function of setting a plurality of virtual tunnels for encapsulating and transferring a frame of a non-general-purpose communication protocol on a general-purpose network. Therefore, three or more multi-tunnel gateway devices configured as described above are connected via a general-purpose network, and a non-general-purpose communication protocol is applied to the physical port of one multi-tunnel gateway device (first multi-tunnel gateway device). Connect the host computer to
A terminal to which a non-general-purpose communication protocol is applied is connected to each physical port of the gateway device (second multi-tunnel gateway device), and by registering the tunnel information in the tunnel information storage means of each multi-tunnel gateway device, If virtual tunnels are respectively set between one multi-tunnel gateway device and each second multi-tunnel gateway device, a plurality of host computers to which the non-general communication protocol is applied and a plurality of non-general communication protocols to which the non-general communication protocol is applied. It is possible to make a virtual multi-drop connection with a terminal via a general-purpose network. That is, it is possible to realize a multi-drop connection configuration that is frequently used with a non-general-purpose communication protocol as it is on a general-purpose network. Moreover, the virtual tunnel can be flexibly set / changed by setting the tunnel information, and thus the multi-drop connection configuration can be flexibly set / changed.
Can be changed.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a virtual multi-drop connection communication system configured by applying a multi-tunnel gateway device according to an embodiment of the present invention.

In FIG. 1, the host computer 11 and the host terminals 12-1 and 12-2 apply a communication protocol unique to the host computer maker (hereinafter referred to as a host maker protocol) to the communication protocol. . The host computer 11 uses the physical line L1 to connect to a physical port of a multi-tunnel gateway device (hereinafter, simply referred to as a gateway device) 13-1 (# 1), for example, physical port 1 (physical port number 1
Port) and is connected to the general-purpose network 14 via the gateway device 13-1. on the other hand,
The host terminals 12-1 and 12-2 are physical ports of gateway devices (multi-tunnel gateway devices) 13-2 (# 2) and 13-3 (# 3) via the physical lines L2 and L3.
For example, it is connected to the physical port 1 and is connected to the general-purpose network 14 via the gateway devices 13-2 and 13-3.

Gateway devices 13-1 (# 1), 13-2
(# 2), 13-3 (# 3) are gateway tables 15-1, 15-2, 15 in which tunnel information for realizing a virtual tunnel between gateway devices via the general-purpose network 14 is registered. -3 is equipped.

Gateway tables 15-1, 15-2, 1
5-3 are gateway devices 13-1, 13-2, 1 respectively
It is stored in a storage device (not shown) included in 3-3.
Here, the gateway tables 15-1, 15-2, 15
-3, between the gateway device 13-1 (# 1) and the gateway device 13-2 (# 2), and the gateway device 1
A virtual tunnel 16 used to encapsulate a frame of the host maker protocol and transfer it via the general-purpose network 14 between the 3-1 (# 1) and the gateway device 13-3 (# 3). Information (tunnel information) for setting -1, 16-2 is registered. By setting the tunnels 16-1 and 16-2 based on this tunnel information, the communication system of FIG.
13 when viewed from the host computer 11 connected to (# 1) and the host terminals 12-1 and 12-2 connected to the gateway devices 13-2 (# 2) and 13-3 (# 3).
This is a connection form equivalent to the multi-drop connection configuration in which the shunt D4 is connected. Here, the host computer 1
1 and the gateway device 13-1 (# 1), and between the host terminals 12-1 and 12-2 and the gateway device 13-2 (#
2), the host maker protocol is used for communication with the gateway device 13-3 (# 3), and the gateway device 13-1 (# 1) and the gateway device 13-2 (# 2),
A general-purpose network protocol (eg, Internet protocol) is used for communication with the tunnel 13-3 (# 3) via the tunnels 16-1 and 16-2.

FIG. 2 shows each gateway device 13 in FIG.
It is a block diagram which shows the structure of -i (#i) (i = 1-3).

The gateway device 13-i has a plurality of physical ports for connecting to a device (host maker protocol device) such as a host computer and a host terminal to which a host maker protocol (non-general communication protocol, non-Internet protocol) is applied, For example, it has physical ports 1 to 4. Here, it is assumed that the physical line Li is connected to the physical port 1 of the gateway device 13-i. The gateway device 13-i also has a connection port with the general-purpose network 14.

The gateway device 13-i includes a communication processing unit (first communication processing unit) 131 and an encapsulation / decapsulation unit 1 in addition to the gateway table 15-i described above.
32, and a general-purpose transport protocol processing unit 133
A general-purpose network protocol processing unit 134, a communication processing unit (second communication processing unit) 135, and a regular monitoring processing unit 136.

The communication processing unit 131 is a device (host computer, connected to each of the physical ports 1 to 4).
It transmits and receives frames to and from the host terminal, etc.). In particular, the communication processing unit 131 transmits / receives a frame via the physical port 1 to / from the physical line Li connecting the host maker protocol device.

The encapsulation / decapsulation unit 132 performs encapsulation (attachment of a header) and decapsulation (removal of the header) of a general-purpose network protocol (for example, Internet protocol) into a transport protocol.

General-purpose transport protocol processing unit 13
3 creates a general-purpose transport protocol header (hereinafter referred to as general-purpose TH). The general-purpose TH is a UDP (User) if the general-purpose network 14 is the Internet.
Datagram Protocol (Header) or TCP (Transmis)
sion control protocol) header.

General-purpose network protocol processing unit 134
Performs routing and creation of a general-purpose network protocol header (hereinafter referred to as general-purpose NH). General-purpose NH
If the general-purpose network 14 is the Internet,
It is an IP (Internet Protocol) header.

The communication processing unit 135 is a general-purpose network 1
The frame is transmitted and received at the connection port with 4. The regular monitoring processing unit 136 uses the remote gateway device 13-j.
(J = 1 to 3, but j ≠ i), a communication state monitoring message such as ICMP (InternetControl Mess
By transmitting an age protocol) message, the communication state between the tunnels is regularly monitored and the communication processing unit 131 is notified when a failure is detected.

FIG. 3 shows the gateway device 13-1 (# 1),
13-2 (# 2), 13-3 (# 3) gateway tables 15-1, 15-2, 15-3 data structure examples and registration in the tables 15-1, 15-2, 15-3 Specific examples of the tunnel information to be generated are shown below.

As shown in FIG. 3, each entry of each gateway table 15-1, 15-2, 15-3 is composed of a local tunnel information field 151 and a remote tunnel information field 152.

In the local tunnel information field 151, of the two ports (tunnel ports) of the virtual tunnel, local tunnel information which is information of the tunnel port on the gateway device side is registered. The local tunnel information includes a physical port number for connecting to a host maker protocol device targeted for frame transfer using a virtual tunnel, a general-purpose network address (for example, IP address), and a general-purpose transport protocol port (for example, UDP or TCP port) number. Here, the general-purpose network address is a network address assigned to the gateway device itself, a network address assigned to a physical port for connecting to the host maker protocol device, or a network address assigned to the host maker protocol device.

In the remote tunnel information field 152, information (remote tunnel information) about the tunnel port on the connection destination gateway device side connected to the gateway device itself via the virtual tunnel is registered. The remote tunnel information is composed of a general-purpose network address (for example, IP address) and a number of a general-purpose transport protocol port (for example, UDP or TCP port). Here, the general-purpose network address is the network address assigned to the connection destination gateway device, the network address assigned to the physical port for connecting to the host maker protocol device connected to the connection destination gateway device, or the connection destination gateway device. This is the network address assigned to the host maker protocol device. Note that the remote tunnel information may include the physical port number of the physical port connected to the host maker protocol device connected to the connection destination gateway device.

Next, an outline of the data flow at the time of data transmission from the host computer 11 to the terminal 12- (k-1) (k = 2, 3) in the communication system of FIG. 1 will be described with reference to FIGS. This will be described with reference to the sequence chart.

First, the host computer 11 includes, in the transmission data 401 to the host terminal 12- (k-1), a host maker protocol header (hereinafter referred to as HH) 402 and a frame check sequence (hereinafter referred to as FCS) 40.
By adding 3, the transmission frame 404 conforming to the host maker protocol is generated (step S1). The host computer 11 transmits this frame 404 to the host terminal 12- (k-1) via the physical line L1 (step S2).

The transmission frame 404 from the host computer 11 is received by the gateway device 13-1 (# 1) via the physical port 1 of the gateway device 13-1. The gateway device 13-1 (# 1) uses the frame 4
When 04 is received, the gateway table 15-1 is referred to, and the received frame 404 is encapsulated in the transport protocol (UDP or TCP) of the general-purpose network protocol (Internet protocol) (step S3). As a result, both the general-purpose TH (general-purpose transport protocol header) 405 and the general-purpose NH (general-purpose network protocol header) 406 and the FCS (frame check sequence) 407 are added to the copy of the received frame 404 for tunnel transfer. , A new frame 408 is generated. Here, the general-purpose TH 405 has a gateway table 15-1.
The general-purpose transport protocol port number (b in the figure) in the remote tunnel information set in the remote tunnel information field 152 is set as the destination port number. In the general-purpose NH, the general-purpose network address (B in the figure) in the remote tunnel information is set as the destination address.

The gateway device 13-1 (# 1) sends a new transmission frame 408, in which a copy of the transmission frame 401 from the host computer 11 is encapsulated, to a general-purpose network address (for example, A) on the local side as a transmission source and The gateway device 13-1 (# 1) and the gateway, which are identified by the combination of the general-purpose transport protocol number (for example, a) and the combination of the general-purpose network address B of the destination remote side and the general-purpose transport protocol number b. Transmission (tunnel transfer) is performed via a virtual tunnel (# 1- # k tunnel) 16-k with the device 13-k (#k) (step S4).

The gateway device 13-k (#k) tunnels the encapsulated transmission frame 408 from the gateway device 13-1 (# 1) to the tunnel (# 1- # k tunnel) 1
Gateway table 15-k when received via 6-k
With reference to, the decapsulation process for the frame 408 is performed (step S5). In step S5,
The number of the physical port that outputs the decapsulated frame is also acquired. By this step S5, the frame 4
A general-purpose NH 406 and general-purpose TH 405 header and FCS 407 are removed from 08, and a transmission frame 414 conforming to the host maker protocol corresponding to the frame 404 from the host computer 11 is generated and the frame 414 The output physical port, for example physical port 1, is determined. As a result, the transmission frame 414 is transmitted by the gateway device 13-k (#k) from the physical port 1 of the gateway device 13-k to the host terminal 12- (k-1) via the physical line Lk ( Step S6).

Upon receipt of the transmission frame 414 from the gateway device 13-k, the host terminal 12- (k-1) extracts the data 401 addressed to itself (step S7).

Next, an outline of the data flow when data is transmitted from the host terminal 12- (k-1) (k = 2, 3) to the host computer 11 in the communication system of FIG.
This will be described with reference to the sequence charts of FIGS. 6 and 7.

First, the host terminal 12- (k-1) adds the HH 602 and the FCS 603 to the transmission data 601 to the host computer 11 to generate the transmission frame 604 conforming to the host maker protocol (step S11). . The host terminal 12- (k-1) uses this frame 60
4 is transmitted to the host computer 11 via the physical line Lk (step S12).

The transmission frame 604 from the host terminal 12- (k-1) is received by the gateway device 13-k (#k) via the physical port 1 of the gateway device 13-k. The gateway device 13-k (#k) uses the frame 60
4 is received, the encapsulation for the received frame 604 is performed by referring to the gateway table 15-k (step S13). As a result, the reception frame 604
A new frame 608 for tunnel transfer in which both headers of the general-purpose TH 605 and the general-purpose NH 606 and the FCS 607 are added to the copy is generated. Where general-purpose TH
In 605, the general-purpose transport protocol port number (a in the figure) in the remote tunnel information set in the remote tunnel information field 152 of the gateway table 15-k is set as the destination port number.
In the general-purpose NH, the general-purpose network address (A in the figure) in the remote tunnel information is set as the destination address.

The gateway device 13-k (#k) uses the new transmission frame 608 in which the copy of the transmission frame 601 from the host terminal 12- (k-1) is encapsulated as the destination general-purpose network address. The gateway device 13-1 (# 1) and the gateway, which are specified by the combination of A and the general-purpose transport protocol number a, and the combination of the general-purpose network address B of the transmission source local side and the general-purpose transport protocol number b. A virtual tunnel (# 1 with the device 13-k (#k)
-# K tunnel) Transmission via 16-k (step S
14).

When the gateway device 13-1 (# 1) receives the encapsulated transmission frame 608 from the gateway device 13-k (#k), it refers to the gateway table 15-1 to retrieve the frame 608. The target decapsulation is performed (step S15). As a result, both the headers of the general-purpose NH 606 and the general-purpose TH 605 and the FCS 607 are removed from the frame 608, which corresponds to the frame 601 from the previous host terminal 12- (k-1) and corresponds to the transmission frame 614 conforming to the host maker protocol. Is generated. This transmission frame 614 is sent to the gateway device 13-1 (# 1) by the gateway device 13-1.
Is transmitted from the physical port 1 to the host computer 11 via the physical line L1 (step S16).

Upon receiving the transmission frame 614 from the gateway device 13-1, the host computer 11 extracts the data 601 addressed to itself (step S17).

Next, referring to the sequence charts of FIGS. 8 and 9, for a specific example of the data flow when data is transmitted from the host computer 11 to the host terminals 12-1 and 12-2 in the communication system of FIG. Explain.

First, the HH 802 and the FCS 80 are sent from the host computer 11 to the transmission frame 804 addressed to the host terminals 12-1 and 12-2, that is, the transmission data 801 (# 1).
It is assumed that the transmission frame 804 conforming to the host maker protocol added with 3 is transmitted on the physical line L1 (step S21). The frame 804 is received by the communication processing unit 131 in the gateway device 13-1 (# 1) via the physical port 1 of the gateway device 13-1 (physical port number 1).

When the communication processing unit 131 receives the frame 804, the encapsulation / decapsulation unit 132 in the gateway device 13-1 (# 1) refers to the gateway table 15-1 and refers to the local tunnel information field. An entry in which the physical port number 1 is set in 151 is searched (step S22). Here, there are two entries in which the physical port number 1 is set in the local tunnel information field 151: entry 1 (entry with entry number 1) and entry 2 (entry with entry number 2). In this case, the encapsulation / decapsulation unit 132 performs frame copy processing to generate the number of copies of the received frame that matches the number of entries for which the physical port number is set, that is, two (step S).
23).

Next, the encapsulation / decapsulation unit 132 of the gateway device 13-1 (# 1) refers to the two entries in the gateway table 15-1 retrieved previously, and sets the remote tunnel information field 152 in the remote tunnel information field 152. A set of the set destination general-purpose network address and general-purpose transport protocol number is acquired (step S24). Here, as is clear from FIG.
The set of "133.130.144.1" and "10001" and the set of "133.130.145.1" and "1000"
1 ”set is acquired.

The encapsulation / decapsulation unit 132 also sets the combination of the general-purpose network address and the general-purpose transport protocol number, which are the transmission sources, set in the local tunnel information field 151 of the two entries in step S24. To get. Here, “133.130.143.1” and “1000
1 ”and“ 133.130.143.1 ”and“ 1 ”
It is assumed that the group “0002” is acquired.

The encapsulation / decapsulation unit 132 sets a set of the destination general-purpose network address and the general-purpose transport protocol number acquired in step S24,
A process (encapsulation process) of encapsulating the two copies is performed based on the set of the general-purpose network address and the general-purpose transport protocol number that are the transmission source (step S25). As a result, the received frame 804
One of the two copies of
5-1 and general-purpose NH806-1 header and FCS807-1
And a new frame 808-1 to which the general-purpose TH805-2 and general-purpose NH806-2 headers and FCS807-2 are added to the other frame.
8-2 and 8-2 are generated. The general-purpose THs 805-1 and 805-2 are created by the general-purpose transport protocol processing unit 133, and the general-purpose NHs 806-1 and 806-2 are created by the general-purpose network protocol processing unit 134.

As shown in FIG. 8, the general-purpose TH805-1 includes the destination port number (general-purpose transport protocol port number) "10001", and the general-purpose NH806-1 includes the destination address (general-purpose network address) "133.13".
0.144.1 "is included. Although not shown, general-purpose TH
805-1 includes the source port number "10001", and the general-purpose NH806-1 includes the source address "133.130.1".
43.1 "is included. On the other hand, the general-purpose TH805-2 includes the destination port number “10001”, and the general-purpose NH806-2 includes the destination address “133.130.145.1”. Although not shown, the general-purpose TH805-2 includes a transmission source port number “10002”, and the general-purpose NH806-2 includes a transmission source address “133.130.143.1”.

The communication processing unit 135 in the gateway device 13-1 (# 1) sends the transmission frames 808-1 and 808-2 generated by the encapsulation process of step S25 to the gateway device 13-1 (# 1). And the gateway device 13-2 (#
2), 13-3 (# 3) and a virtual tunnel (# 1-
# 2 tunnel) 16-1, (# 1- # 3 tunnel) 16-2
(Tunnel transfer) via (step S26-
1, S26-2). Tunnel (# 1- # 2 tunnel) 16-
1 is a combination of a general-purpose network address “133.130.143.1” and a general-purpose transport protocol number “10001” on the local side which is a transmission source,
General-purpose network address "1" on the remote side that is the destination
It is specified by the combination of 33.130.144.1 ”and the general-purpose transport protocol number“ 10001 ”. On the other hand, the tunnel (# 1- # 3 tunnel) 16-2 is
A combination of the general-purpose network address "133.130.143.1" on the transmission source side and the general-purpose transport protocol number "10002" and the general-purpose network address "13" on the remote side which is the destination.
It is specified by the combination of "3.130.145.1" and the general-purpose transport protocol number "10001".

Gateway devices 13-2 (# 2), 13-3
The encapsulation / decapsulation unit 132 in (# 3) receives the encapsulated transmission frames 808-1 and 808-2 from the gateway device 13-1 (# 1) in the tunnels 16-1 and 1.
When it is received by the communication processing unit 135 via 6-2, it is determined whether or not decapsulation is necessary by referring to the gateway tables 15-2 and 15-3 (steps S27-1, S).
27-2). Here, the gateway device 13-2 (# 2),
13-3 (# 3) encapsulation / decapsulation unit 132
Is a general-purpose TH 805 of received frames 808-1 and 808-2.
-1, 805-2, the general-purpose transport protocol port number that matches the destination port number is stored in the local tunnel information field 151.
General-purpose transport protocol port numbers that match the source port numbers contained in 1, 805-2 are set in the remote tunnel information field 152, respectively.
And the general-purpose NH806 of the reception frames 808-1 and 808-2
1, a general-purpose network address matching the destination address included in 806-2 is stored in the local tunnel information field 151 as a general-purpose network address matching the source address included in the NH 806-1 or 806-2. When each is set in the remote tunnel information field 152, that is, the received frame 808-
It is determined that decapsulation is necessary when the 1,808-2 is transferred via the tunnels 16-1, 16-2.

Gateway devices 13-2 (# 2), 13-3
When the encapsulation / decapsulation unit 132 in (# 3) determines that decapsulation is necessary, the received frame 808
-1, 808-2 is subjected to decapsulation processing (steps S28-1, S28-2). This makes the frame 8
08-1, 808-2 to general-purpose NH806-1, 806-2 and general-purpose TH805-1, 805-2 header and FCS807
1, 807-2 are removed, and the transmission frames 814-1 and 814-2 corresponding to the frame 804 from the previous host computer 11 are compliant with the host maker protocol.
Is generated. Gateway device 13-2 (# 2), 13
-3 (# 3), in steps S27-1 and 27-2,
From the physical port number “1” registered in the entry in the gateway tables 15-2 and 15-3 referred to above,
The output physical port 1 of the transmission frames 814-1 and 814-2 is determined.

Therefore, the gateway device 13-2 (# 2),
The communication processing unit 131 in 13-3 (# 3) transmits the transmission frames 814-1 and 814-2 from its own physical port 1 to the host terminals 12-1 and 12-2 via the physical lines L2 and L3. To do.

As described above, the host computer 11 and the host terminals 12-1 and 12-2 are different in communication protocol from the communication protocol (host maker protocol) of the host computer 11 and the host terminals 12-1 and 12-2.
That is, the general-purpose network 1 of the general-purpose network protocol
Despite being connected via 4, the host computer 11 sends a copy of the transmission frame conforming to the host maker protocol to the host terminals 12-1 and 12-2, and the host terminals 12-1 and 12-2. -2 can be received.

Next, with reference to the sequence charts of FIGS. 10 and 11, for a specific example of the data flow when data is transmitted from the host terminals 12-1 and 12-2 to the host computer 11 in the communication system of FIG. Explain.

First, transmission frames 104-1, 104 from the host terminals 12-1, 12-2 to the host computer 11 are sent.
-2, that is, transmission data 101-1 (# 1), 101-2 (#
2), HH102-1, 102-2 and FCS103-1,
Transmission frames 104-1, 104-2 conforming to the host maker protocol with 103-2 added are physical lines L2, L
3 is transmitted (steps S31-1, S3).
1-2). The frames 104-1 and 104-2 are connected to the physical ports 1 of the gateway devices 13-2 and 13-3 by the communication processing unit 131 in the gateway devices 13-2 (# 2) and 13-3 (# 3). Received through.

Gateway devices 13-2 (# 2), 13-3
When the communication processing unit 131 receives the frames 104-1 and 104-2, the encapsulation / decapsulation unit 132 in (# 3) refers to the gateway tables 15-2 and 15-3 to refer to the local tunnel. An entry in which the physical port number 1 is set in the information field 151 is searched (steps S32-1, S32-2). Gateway table 15
In the -2 and 15-3, the entry in which the physical port number 1 is set in the local tunnel information field 151 is only the entry 1. In this case, the encapsulation / decapsulation unit 132 of the gateway devices 13-2 (# 2) and 13-3 (# 3) performs frame copy processing to generate one copy of the received frame (step S33-). 1,
S33-2).

Next, the gateway device 13-2 (# 2),
13-3 (# 3) encapsulation / decapsulation unit 132
Is the gateway table 15-2, 15-3 searched previously
The entry in is referred to and the set of the destination general-purpose network address and general-purpose transport protocol number set in the remote tunnel information field 152 is acquired (steps S34-1 and S34-2). here,
As is clear from FIGS. 3B and 3C, in the gateway device 13-2 (# 2), “133.130.143.
The set of 1 ”and“ 10001 ”is the gateway device 13
In -3 (# 3), the groups of "133.130.143.1" and "10002" are acquired, respectively.

Gateway devices 13-2 (# 2), 13-3
The encapsulation / decapsulation unit 132 of (# 3) also
In steps S34-1 and S34-2, the set of the general-purpose network address and the general-purpose transport protocol number which is the transmission source and is set in the local tunnel information field 151 of the entry is acquired. Here, in the gateway device 13-2 (# 2), "133.
The combination of “130.144.1” and “10001” is “133.130.1” in the gateway device 13-3 (# 3).
The gateway devices 13-2 (# 2), 13-3 (#
3) The encapsulation / decapsulation unit 132 sets the combination of the destination general-purpose network address and the general-purpose transport protocol number acquired in steps S34-1 and S34-2, the general-purpose network address and the general-purpose transport that are the transmission source. Based on the set of port protocol numbers, encapsulation processing for the above copy is performed (step S3).
5-1 and S35-2). As a result, the reception frame 104-
General-purpose TH105-1, 105-2 for copying 1, 104-2
General purpose NHs 106-1 and 106-2, FCS 107-1,
New frames 108-1 and 10 to which 107-2 is added
8-2 is generated.

As shown in FIG. 10, the general-purpose TH 105-1 includes the destination port number "10001" and the general-purpose NH 106-1.
-1 includes the destination address "133.130.143.1". Although not shown, the general-purpose TH 105-1 includes a transmission source port number “10001”, and the general-purpose NH 106-1 includes a transmission source address “133.130.144.1”. On the other hand, the general-purpose TH105-2 has the destination port number "10002".
, The general-purpose NH106-2 has a destination address "133.1".
Including 30.143.1 ". Although not shown, a general-purpose T
H105-2 includes the source port number "10001",
The general-purpose NH106-2 transmits the source address "133.130.
145.1 ".

Gateway devices 13-2 (# 2), 13-3
The communication processing unit 135 in (# 3) uses step S35-1,
Transmission frame 10 generated by the encapsulation process 35-2
8-1 and 108-2 are virtual tunnels (# 1- # 2 tunnel) between the gateway device 13-1 (# 1) and the gateway devices 13-2 (# 2) and 13-3 (# 3). ) 16-1,
(# 1- # 3 tunnel) 16-2 is used for transmission (tunnel transfer) (steps S36-1, S36-2). At this time, the gateway device 13-2 (# 2) and the gateway device 1
3-3 (# 3), no tunnel setting has been made, so frame transmission from the gateway device 13-2 (# 2) to the gateway device 13-3 (# 3) and gateway device 13-3 (# 3) to the gateway device 13-2 (#
No frame is transmitted to 2).

The encapsulation / decapsulation unit 132 in the gateway device 13-1 (# 1) is the gateway device 1
The encapsulated transmission frames 108-1, 108-2 from 3-2 (# 2), 13-3 (# 3) are tunnels 16-1, 1
When it is received by the communication processing unit 135 via 6-2, it refers to the gateway table 15-1 and determines whether or not decapsulation is necessary (step S37). Here, the encapsulation / decapsulation unit 132 of the gateway device 13-1 (# 1) matches the destination port number included in the general-purpose THs 105-1 and 105-2 of the received frames 108-1 and 108-2. In the local tunnel information field 151, the general-purpose transport protocol port number to be used is set, and in the remote tunnel information field 152, the general-purpose transport protocol port number that matches the transmission source port number included in the general-purpose THs 105-1 and 105-2 is set. In the local tunnel information field 151, the general-purpose network addresses that are respectively set and match the destination addresses included in the general-purpose NHs 106-1 and 106-2 of the received frames 108-1 and 108-2 are stored in the local tunnel information field 151. -2
The generic network address that matches the source address contained in the remote tunnel information field 152.
, It is determined that the decapsulation is necessary when the received frames 108-1, 108-2 are transferred via the tunnels 16-1, 16-2. To be done.

When the encapsulation / decapsulation unit 132 of the gateway device 13-1 (# 1) determines that decapsulation is necessary, the decapsulation processing for the received frames 108-1 and 108-2 is performed. Is performed (step S38).
This allows general-purpose NH from the frames 808-1 and 808-2.
106-1 and 106-2 and general-purpose TH105-1, 105-2 and F
Frames 104-1 and 104-2 from the previous host terminals 12-1 and 12-2 from which the CSs 107-1 and 107-2 have been removed
The transmission frames 114-1 and 114-2 corresponding to the host manufacturer protocol are generated. In step S37, the gateway device 13-1 (# 1) outputs the transmission frames 114-1 and 114-2 from the physical port number “1” registered in the entry in the gateway table 15-1 referred to above. Determine the physical port 1.

Therefore, the communication processing unit 131 in the gateway device 13-1 (# 1) transmits the transmission frames 114-1 and 114.
-2 is transmitted from its own physical port 1 to the host computer 11 via the physical line L1.

As described above, the host computer 11 and the host terminals 12-1 and 12-2 are connected via the general-purpose network 14 having a communication protocol different from the communication protocol of the host computer 11 and the host terminals 12-1 and 12-2. Host terminals 12-1 and 12
A copy of the transmission frame conforming to the host maker protocol from -2 can be transmitted to the host computer 11 and received by the host computer 11.

As described above, in the present embodiment, the multi-drop connection configuration which is frequently used by the host maker protocol (non-general-purpose communication protocol) can be realized as it is on the general-purpose network 14. For this reason,
Unlike the conventional multi-drop connection configuration using a shunt as shown in FIG. 3, there is no physical connection limitation (connection position, cable distance, etc.), and there is no dependence on the installation position. Therefore, a completely virtual multi-drop connection configuration can be realized.

In the present embodiment, the regular monitoring processing unit 136 in each of the gateway devices 13-1 to 13-3 regularly monitors the general-purpose network 14 and
When the failure is detected, the gateway device 13-1 to 13
-Notify the failure to the host maker protocol device (host computer or terminal) connected to the physical port of -3. Therefore, each of the gateway devices 13-1 to 13-1
The regular monitoring processing unit 136 of 3-3, with the remote gateway device for which a tunnel setting is established with itself,
The ICMP message is periodically transmitted to confirm the response. If the remote gateway device does not respond to the ICMP message, the regular monitoring processing unit 136 determines that the general-purpose network 14 has failed.
Link down the physical layer of the physical port (accommodation port) to which the host maker protocol device is connected,
Notify the device (host computer or terminal) of the failure.

FIG. 12 is a block diagram showing a concrete example in which the communication system of FIG. 1 is applied to a financial online system. The same parts as those in FIG. 1 are designated by the same reference numerals.

In the system shown in FIG. 12, a host computer corresponding to the host computer 11 shown in FIG. 1 has a non-general-purpose communication protocol of HDLC (High-level Data Li).
nk Control) procedure or SDLC (Synchronous Data)
Host computer 1 to which the Link Control procedure is applied
10 is used. Similarly, the host terminal 1 in FIG.
A cash dispenser (CD) 121 and an automatic teller machine (ATM) 122 to which an HDLC procedure or an SDLC procedure is applied are used as terminals corresponding to the 2-1 and the host terminal 12-2, respectively.

The host computer 110 passes through the gateway device 130-1 (# 1) (corresponding to the gateway device 13-1 (# 1) in FIG. 1) (corresponding to the general-purpose network 14 in FIG. 1). It is connected to the Internet 140 that applies the Internet protocol. The cache dispenser (CD) 121 is a gateway device 1 (corresponding to the gateway device 13-2 (# 2) in FIG. 1).
30-2 (# 2), automated teller machine (ATM)
122 is through a gateway device 130-3 (# 3) (corresponding to the gateway device 13-3 (# 3) in FIG. 1),
Each is connected to the Internet 140.

Gateway devices 130-1 (# 1), 13
In the gateway tables 150-1, 150-2, and 150-3 of 0-2 (# 2) and 130-3 (# 3), the gateway device 130-1 (# 1) and the gateway device 130-2 (#
2) and tunnel information for setting virtual tunnels 160-1 and 160-2 between the gateway device 130-1 (# 1) and the gateway device 130-3 (# 3), respectively. Is registered.

In the financial online system of FIG. 12, the host computer 100, the cash dispenser (CD) 121, and the automatic teller machine (ATM) 12
2 is a multi-drop connection configuration with a virtual tunnel 16
It can be realized on the general-purpose network 14 by 0-1 and 160-2. As a result, by realizing the financial online system, which was conventionally constructed with a dedicated line, on the Internet 140 as a general-purpose network while maintaining the assets of existing host computers and terminals, it is possible to significantly reduce the line cost and Efficiency can be improved by sharing the network infrastructure.

The present invention is not limited to the above-described embodiment, and can be variously modified in an implementation stage without departing from the spirit of the invention. Furthermore, the embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, the problem described in the section of the problem to be solved by the invention can be solved, and the effect described in the section of the effect of the invention can be solved. If you get
A configuration in which this component is deleted can be extracted as an invention.

[0069]

As described in detail above, according to the present invention, it is possible to realize a multi-tunnel function for setting a plurality of virtual tunnels for encapsulating and transferring a frame of a non-general-purpose communication protocol on a general-purpose network. Moreover, this multi-tunnel function can realize a multi-drop connection configuration on a general-purpose network.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a virtual multi-drop connection communication system configured by applying a multi-tunnel gateway device according to an embodiment of the present invention.

FIG. 2 is each gateway device 13-i (#i) in FIG.
The block diagram which shows the structure of (i = 1-3).

FIG. 3 shows gateway devices 13-1 (# 1) and 13-2 (#
2), 13-3 (# 3) gateway table 15-1,
15-2 and 15-3 data structure examples and the table 15-
The figure which shows the specific example of the tunnel information registered into 1, 15-2, and 15-3.

4 is a part of a sequence chart for explaining an outline of a data flow when data is transmitted from a host computer 11 to a terminal 12- (k-1) (k = 2, 3) in the communication system of FIG. FIG.

5 is a sequence chart for explaining the outline of the data flow when data is transmitted from the host computer 11 to the terminal 12- (k-1) (k = 2, 3) in the communication system of FIG. FIG.

6 is a host terminal 12- in the communication system of FIG.
The figure which shows a part of sequence chart for demonstrating the outline of the flow of data at the time of data transmission from (k-1) (k = 2, 3) to the host computer 11.

7 is a host terminal 12- in the communication system of FIG.
The figure which shows the remainder of the sequence chart for demonstrating the outline of the data flow at the time of data transmission from (k-1) (k = 2, 3) to the host computer 11.

8 is a diagram showing a part of a sequence chart for explaining a specific example of a data flow when data is transmitted from the host computer 11 to the host terminals 12-1 and 12-2 in the communication system of FIG.

9 is a diagram showing the rest of the sequence chart for explaining a specific example of the data flow when data is transmitted from the host computer 11 to the host terminals 12-1, 12-2 in the communication system of FIG.

10 is a host terminal 12 in the communication system of FIG.
-1, 12-2 is a diagram showing a part of a sequence chart for explaining a specific example of a data flow when transmitting data from the host computer 11 to the host computer 11.

11 is a host terminal 12 in the communication system of FIG.
-1, 12-2 is a diagram showing the rest of the sequence chart for explaining a specific example of the flow of data when transmitting data from the host computer 11 to the host computer 11.

12 is a block diagram showing a specific example in which the communication system of FIG. 1 is applied to a financial online system.

FIG. 13 is a block configuration diagram of a communication system to which a conventional multi-drop connection configuration is applied.

[Explanation of symbols]

11, 110 ... Host computers 12-1, 12-2 ... Host terminals 13-1, 13-2, 13-3, 130-1, 130-2, 130
-3 ... Gateway device (multi-tunnel gateway device) 14 ... General-purpose network 15-1, 15-2, 15-3, 150-1, 150-2, 150
-3 ... Gateway table 16-1, 16-2, 160-1, 160-2 ... Tunnel 140 ... Internet (general purpose network) 121 ... Cash dispenser (terminal) 122 ... Automatic teller machine (terminal)

Claims (7)

[Claims] 1. A multi-tunnel gateway device having a multi-tunnel function, wherein a frame of the non-general-purpose communication protocol is transmitted and received through a physical port for connecting to a non-general-purpose communication protocol device to which the non-general-purpose communication protocol is applied. And a second communication processing unit for transmitting and receiving a frame of the general-purpose network protocol via a connection port between the first communication processing unit for performing the above-mentioned and a general-purpose network for applying the general-purpose network protocol, and a frame for the non-general-purpose communication protocol. Which is a virtual tunnel used for encapsulating and transferring the packet via the general-purpose network. Tunnel information for designating a virtual tunnel set between the own gateway device and another gateway device is registered. Tunnel information storage means, and the first communication processing unit. The frame received by the means,
Encapsulation processing for encapsulating so as to be transferred through a virtual tunnel designated by the tunnel information registered in the tunnel information storage means, and a virtual tunnel designated by the tunnel information registered in the tunnel information storage means A multi-tunnel gateway apparatus comprising: an encapsulation / decapsulation means for performing decapsulation processing for decapsulating the frame transferred through the second communication means and received by the second communication means. 2. The tunnel information registered in the tunnel information storage means is local tunnel information that is information of a port on the gateway device side of the corresponding virtual tunnel, and is a target of frame transfer using the virtual tunnel. Local tunnel information including a physical port number for connecting to a non-general-purpose communication protocol device and a general-purpose transport protocol port number, and the virtual information on the side of another gateway device connected to the own gateway device via the virtual tunnel. 2. The multi-tunnel gateway device according to claim 1, wherein the remote tunnel information is information on a port of the tunnel, and is composed of remote tunnel information including a general-purpose network address and a general-purpose transport protocol port number. 3. A regular monitoring processing means for periodically transmitting a communication state monitoring message to another gateway device connected to the own gateway device via the virtual tunnel, and detecting a failure according to a response to the message. The multi-tunnel gateway apparatus according to claim 1, further comprising: 4. The first multi-tunnel according to claim 1.
A general-purpose network in which a gateway device, a plurality of second multi-tunnel gateway devices according to claim 1, and the first multi-tunnel gateway device and the plurality of second multi-tunnel gateway devices are connected. A general-purpose network to which a protocol is applied, a host computer to which a non-general-purpose communication protocol is applied, which is connected to a physical port of the first multi-tunnel gateway device, and each of the second multi-tunnel gateway devices. A terminal to which the non-general-purpose communication protocol is applied, the terminal being connected to a physical port of the corresponding second multi-tunnel gateway device; and the tunnel information of the first multi-tunnel gateway device. In the storage means, via the general-purpose network Tunnel information designating a virtual tunnel set between the first multi-tunnel gateway device itself and each of the second multi-tunnel gateway devices is registered, and each of the second multi-tunnel gateway devices is registered. The tunnel information storage means stores tunnel information that specifies a virtual tunnel set between the second multi-tunnel gateway device itself and the first multi-tunnel gateway device via the general-purpose network. A virtual multi-drop connection communication system characterized by being registered. 5. The encapsulation / decapsulation means of the first multi-tunnel gateway apparatus has a copy of the frame received by the first communication processing means registered in the tunnel information storage means. 5. The virtual machine according to claim 4, wherein a number of virtual tunnels designated by the tunnel information are generated, encapsulated for each copy, and transferred by the second communication means via the corresponding virtual tunnel. Multi-drop connection communication system. 6. The first multi-tunnel according to claim 1.
A general-purpose network in which a gateway device, a plurality of second multi-tunnel gateway devices according to claim 1, and the first multi-tunnel gateway device and the plurality of second multi-tunnel gateway devices are connected. A general-purpose network to which a protocol is applied, a host computer to which a non-general-purpose communication protocol is applied, which is connected to a physical port of the first multi-tunnel gateway device, and each of the second multi-tunnel gateway devices are provided. A communication method in a virtual multi-drop connection communication system comprising a terminal to which the non-general-purpose communication protocol is applied, the terminal being connected to a physical port of the corresponding second multi-tunnel gateway device, From the host computer to the first multiton Transmitting a frame of the non-general-purpose communication protocol to the physical port of the gateway device, and the first multi-tunnel gateway device receives the frame transmitted from the host computer via the physical port. And a copy of the frame received by the first multi-tunnel gateway device.
The first multi-tunnel gateway device generates as many virtual tunnels as the number of virtual tunnels specified by the tunnel information registered in the tunnel information storage means of the gateway device, and encapsulates each copy according to the tunnel information. And a step of generating a transmission frame for each of the virtual tunnels, and a connection destination of the generated transmission frame for each of the virtual tunnels from the first multi-tunnel gateway device via the corresponding virtual tunnel. And the step of receiving the frame transmitted from the first multi-tunnel gateway device via the virtual tunnel by the second multi-tunnel gateway device. And the second multi-tunnel gateway Decapsulating the frame received by the device in the second multi-tunnel gateway device, and the decapsulated frame from the physical port of the second multi-tunnel gateway device to the terminal. And a step of transmitting, the communication method in a virtual multi-drop connection communication system. 7. The step of transmitting a frame of the non-general-purpose communication protocol from the terminal to the physical port of the corresponding second multi-tunnel gateway device, the second multi-tunnel gateway device receiving the frame. By encapsulating the frame according to the tunnel information registered in the tunnel information storage means of the second multi-tunnel gateway device, a transmission frame for transferring via the virtual tunnel specified by the tunnel information is encapsulated. And a step of transmitting the generated transmission frame from the second multi-tunnel gateway apparatus to the first multi-tunnel gateway apparatus of a connection destination via the corresponding virtual tunnel, From the second multi-tunnel gateway device Receiving the frame transmitted through the virtual tunnel by the first multi-tunnel gateway device, and the frame received by the first multi-tunnel gateway device in the first multi-tunnel gateway device The method further comprising the steps of: decapsulating in step 1; and transmitting the decapsulated frame from the physical port of the first multi-tunnel gateway device to the host computer. 7. A communication method in the virtual multi-drop connection communication system according to 6.