JP4312650B2 - Access network system and method - Google Patents

Description

  The present invention relates to an access network in Internet communication.

  Currently, in the FLET'S (registered trademark) service provided by Nippon Telegraph and Telephone Corporation and the TEPCO (registered trademark) optical service provided by TEPCO, a plurality of ISP (Internet Service Provider) services can be selected for the access service provider. Therefore, the ISP service is identified using authentication by PPPoE (Point-to-Point over Ethernet (registered trademark)).

  In order to select such an ISP service, it is necessary to use a session control protocol such as PPPoE or IPSec. Therefore, the user is forced to set a session control protocol.

  Furthermore, in order to perform communication by Internet VPN (Virtual Private Network) service using IPSec, SSL (Secure Sockets Layer), etc. between a user and a company base, PPPoE is performed between the user equipment and the station equipment. In addition, it is necessary to create an IP tunnel such as IPSec or SSL between the user and the base of the company in an IP tunnel created by IPSEC or the like, so that the communication speed in the user equipment decreases.

  In session control protocols such as PPPoE and IPSec, connexion-type communication having a communication state called a session is performed. Therefore, the station equipment requires a function for terminating PPPoE, IPSec, and the like, and the apparatus cost increases.

  On the other hand, an example of a communication network using an Internet VPN service is disclosed (see Patent Document 1). This communication network uses a plurality of network devices that accommodate communication terminals via ports provided with VLANs, and a plurality of network units that accommodate external lines, thereby ensuring security between communication terminals and providing a plurality of ISPs. It can be easily connected. However, the problem described above exists also in this communication network.

JP 2003-258831 A (paragraphs [0010] [0016])

  Accordingly, the present invention has been made to solve the above-described problems, and an object thereof is Ethernet (registered trademark) access based on Ethernet (registered trademark) technology that does not use a session control protocol such as PPPoE or IPSec. It is to provide a system and method capable of realizing a service.

  Another object of the present invention is to provide a system and method that can eliminate the state management required in the session control protocol and can reduce the cost of devices constituting an access network.

  Another object of the present invention is to provide a system and method capable of preventing a reduction in communication speed when a user uses IPSec, SSL, or the like in an Internet VPN service or the like.

  Another object of the present invention is to provide a system and method capable of managing the correspondence between ISP service selection and user line and preventing access to services outside the contract.

  Another object of the present invention is to limit the packet transfer range for each ISP service and improve the efficiency of packet transfer in the core network with respect to the core network composed of transfer devices compatible with IEEE 802.1Q VLAN-ID. It is to provide a possible system and method.

The access network system and the packet transfer method performed by the access network according to the present invention include a service network for a service provider to provide a predetermined communication service to a user, a core network connected to the service network, and a user operation. A service distribution device provided in an access network system that performs packet transfer control between the user network and the core network under a service providing system that realizes a communication service by a user network including a communication terminal is transmitted from the user network. Intra-station terminating device having means for receiving the received packet, attaching a first extension tag corresponding to the line number from the user network to the received received packet, and transmitting to the service distribution device The second extended tag assigned corresponding to the line number from該局the termination device, specified in IEEE802.1Q included in said received packet the first expansion tag and a second extended tag of the service provider is defined The first extended tag, the second extended tag, and an access service list in which the second extended tag and the VLAN-ID are associated with each other. The extension tag and the VLAN-ID of the first access tag are compared with the first extension tag, the second extension tag and the VLAN-ID in the service access list. If they match, the received packet is transmitted to the service network represented by the VLAN-ID. If they do not match, the received packet is discarded.

  According to the present invention, the access network can identify the service network that provides the communication service based on the VLAN-ID defined by IEEE802Q, and the user can use the VLAN-ID at the communication terminal of the user network. Is added to the packet, the communication service can be selected. The access network can identify the user network based on the extension tag.

  According to the present invention, the access network system can identify a user network based on a two-layered expansion tag including the first and second expansion tags.

  Further, according to the access network system and the packet transfer method performed by the access network according to the present invention, the service distribution apparatus stores in advance correspondence information between an expansion tag corresponding to a line that receives a packet from a user network and a VLAN-ID. The received packet is discarded based on the stored correspondence information.

  According to the present invention, since the access network system manages the correspondence information between the expansion tag and the VLAN-ID, the access service provider operating the access network system can manage the communication services available to the user. it can. Further, since the packet is discarded by the access control based on the correspondence information between the extension tag and the VLAN-ID, access to the service network can be prevented so as not to provide the user with a communication service outside the contract. . Furthermore, since the packet transfer control is performed using the statically assigned expansion tag and VLAN-ID, the state management required when using a session control protocol such as PPPoE or IPSec becomes unnecessary. The apparatus cost can be reduced.

  The access network system of the present invention and the packet transfer method performed by the access network may be configured such that when the service distribution device transfers the packet to the service network via the core network, the extension tag is deleted from the packet. Features.

  According to the present invention, when the user network and the service network are connected by the core network, the service distribution device deletes the extension tag and converts it into the original IEEE 802.1Q frame format. The range can be limited, and unnecessary packet transfers can be suppressed in the core network.

  As described above, according to the present invention, an Ethernet (registered trademark) access service system based on the Ethernet (registered trademark) technology that does not use a session control protocol such as PPPoE or IPSec can be configured. As a result, the user can save the trouble of setting these session control protocols, and can easily select the ISP service and receive the service. In addition, an access service provider can configure an Ethernet (registered trademark) access service system with an inexpensive device that does not require termination of these session control protocols, and can easily manage ISP service contracts with users. It can be carried out.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
〔Constitution〕
FIG. 1 shows a configuration diagram of an Ethernet (registered trademark) access service system according to an embodiment of the present invention. This Ethernet (registered trademark) access service system includes in-house terminal devices 11-1 to 11-i (hereinafter collectively 11), in-station terminal devices 2-1 to 2-j (hereinafter collectively 2), service It comprises a distribution device 3 and a management device 4. In-home terminal devices 11-1 and 11-2 and in-station terminal device 2-1, in-home terminal devices 11-3 and 11-i and in-station terminal device 2-j, in-station terminal device 2 and service distribution device 3, service distribution device 3 The management device 4 is connected to each other by a communication line. The service station 1 that realizes the access service provided by the access service provider is provided with an in-station terminal device 2, a service distribution device 3, and a management device 4, and the user home 10-1 of the user who receives the ISP service is provided. -10-i (hereinafter collectively referred to as 10) include an in-home terminal device 11, Ethernet (registered trademark) switches 12-1 to 12-i (hereinafter collectively referred to as 12) such as layer 2 switches, personal computers, and the like Communication terminals 13-1 to 13-i (hereinafter collectively referred to as 13). Internet service providers who provide ISP services constitute ISP networks 21-1 to 21-k (hereinafter collectively referred to as 21). Although FIG. 1 shows a configuration in which two in-house terminal devices are connected to one in-station terminal device, a configuration in which one or three or more in-home terminal devices are connected may be used. Here, the above-mentioned i, j, and k are natural numbers.

  In addition, a communication terminal 13 is connected to the home terminal device 11 via an Ethernet (registered trademark) switch 12 provided in the user home 10. Note that the communication terminal 13 may be directly connected to the in-home terminal device 11. The service distribution device 3 of the service station 1 is connected to the ISP network 21 via the core network 20.

  The Ethernet (registered trademark) access service system configured as described above performs ISP connection management between the communication terminal 13 operated by the user and the ISP network 21 and contract management regarding the use of the ISP service. As a result, the user can use the communication terminal 13 to receive the ISP service provided by the ISP provider. In addition, in order for the user to receive the ISP service, it is necessary to make an ISP service contract with an access service provider that manages the service station 1.

  The management device 4 manages the ISP service contracted by the user. Specifically, the management device 4 uses, for each user, a VLAN-ID (service identifier) used for identifying the ISP service, the in-home terminal device 11, the in-station terminal device 2, and the service distribution based on the ISP service contract. Management is performed using a correspondence table with expansion tags (line identifiers) representing packet path information between devices 3. This correspondence table is set in advance by the access service provider. FIG. 5 shows an example of the correspondence table. This correspondence table includes a user name, an expansion tag, and a VLAN-ID, and the user name, the user line, and the contract service are associated with each other by these information. In the example of FIG. 5, the user 1 is using the line 1-1 (the intra-station terminating device 2-1 and the residential terminating device 11-1), the contract service is 1 (ISP network 21-1), and the user 2 is the line 1 -2 (intra-station termination device 2-1 and in-home termination device 11-2), the contract service is 1 and 2 (ISP networks 21-1 and 21-2), and the user 3 is the line j-3 (intra-station termination) Device 2-j, home end device 11-3), contract service is 2 (ISP network 21-2), user 4 is line ji (intra-station end device 2 -j, home end device 11 -i ) And the contract service is 2, k (ISP network 21-2, 21-k).

  As shown in FIG. 6, the service distribution device 3 includes user interfaces 3-1-1, 3-1-2-3-1-j (hereinafter, collectively 3-1), a forwarding database (FDB) 3-3. 2, a transfer control unit 3-3, a packet filter / service distribution unit 3-4, a service access control list 3-5, a core network interface 3-6, and a management device interface 3-7. The service access control list 3-5 is a list set by the management apparatus 4 via the management apparatus interface 3-7, and corresponds to the information similar to the correspondence table shown in FIG. 5 or the VLAN-ID and the expansion tag. The attached information is stored. The forwarding database 3-2 stores information in which the expansion tag is associated with the MAC address of the user communication terminal 13.

[Operation (User → ISP)]
Next, an operation of transferring an Ethernet (registered trademark) packet from the user to the ISP will be described. When the user operates the communication terminal 13 to receive the ISP service, the communication terminal 13, the Ethernet (registered trademark) switch 12, or the router (not shown) is connected to a VLAN (Virtual Local Area Network) corresponding to the contracted ISP service. The ID is assigned to the Ethernet (registered trademark) packet, and the Ethernet (registered trademark) packet is transmitted to the service station 1 via the in-home terminal device 11. FIG. 2 shows a format example of an Ethernet (registered trademark) packet 101 with VLAN-ID according to IEEE 802.1Q. This Ethernet (registered trademark) packet 101 with VLAN-ID is composed of a destination MAC address, a source MAC address, a tag protocol ID, tag control information, a packet length / type, data, and a frame check sequence. The tag control information includes priority information, an indicator, and a VLAN-ID assigned by the communication terminal 13 or the Ethernet (registered trademark) switch 12.

  Upon receipt of the Ethernet (registered trademark) packet 101 from the in-house terminal device 11, the in-station terminal device 2 transmits the first extension tag corresponding to the line connecting the in-station terminal device 2 and the in-home terminal device 11 to the Ethernet (registered trademark). ) Is added to the packet 101, an Ethernet (registered trademark) packet 102 is generated, and the Ethernet (registered trademark) packet 102 is transmitted to the service distribution device 3. For example, when the in-station terminal device 2-1 receives from the in-home terminal device 11-1, "1" is assigned as the first extension tag, and "2" is added when received from the in-home terminal device 11-2. To do. In this way, the in-station terminal device 2 assigns a different unique tag to each line connecting the in-station terminal device 2 and the in-home terminal device 11. FIG. 3 shows a format example of the Ethernet (registered trademark) packet 102 with the first extension tag. The Ethernet (registered trademark) packet 102 with the first extension tag includes a destination MAC address, a source MAC address, a first extension tag given by the intra-station terminal device 2, a tag protocol ID, tag control information, a packet length / It consists of type, data and frame check sequence. Tag control information includes priority information, an indicator, and a VLAN-ID.

  When the service distribution device 3 receives the Ethernet (registered trademark) packet 102 from the intra-station termination device 2, the user interface 3-1 is connected to the line connecting the user interface 3-1 of the service distribution device 3 and the intra-station termination device 2. A corresponding second extension tag is attached to the Ethernet (registered trademark) packet 102 to generate the Ethernet (registered trademark) packet 103, and the Ethernet (registered trademark) packet 103 is transferred to the transfer control unit 3-3 and the packet filter / service. The data is output to the distribution unit 3-4.

  For example, when the service distribution device 3 receives the Ethernet (registered trademark) packet 102 from the intra-station termination device 2-1, the user interface 3-1-1 gives “1” as the second extension tag. In addition, when received from the intra-station terminating device 2-2, the user interface 3-1-2 gives “2” as the second extension tag. As described above, the user interface 3-1 assigns a unique tag different for each line connecting the service distribution device 3 and the intra-station terminal device 2. FIG. 4 shows a format example of the Ethernet (registered trademark) packet 103 with the second extension tag. This Ethernet (registered trademark) packet 103 with the second extension tag includes a destination MAC address, a source MAC address, a second extension tag assigned by the service distribution device 3, a first extension tag, a tag protocol ID, and a tag. It consists of control information, packet length / type, data, and frame check sequence. Tag control information includes priority information, an indicator, and a VLAN-ID.

  When the Ethernet (registered trademark) packet 103 is input, the transfer control unit 3-3 receives the source MAC address of the Ethernet (registered trademark) packet 103 and the expansion tag (the first expansion tag and the second expansion tag). The correspondence is registered in the forwarding database 3-2.

  When the Ethernet (registered trademark) packet 103 is input, the packet filter / service distribution unit 3-4 receives the extension tag and VLAN-ID of the Ethernet (registered trademark) packet 103, the extension tag of the service access control list 3-5, and Compare with VLAN-ID. If they match, filter processing is performed, and the Ethernet (registered trademark) packet 103 is output to the core network interface 3-6. If they do not match, the Ethernet (registered trademark) packet 103 is discarded.

  When the Ethernet (registered trademark) packet 103 is input, the core network interface 3-6 removes the extension tag from the Ethernet (registered trademark) packet 103 and identifies the Ethernet (registered trademark) packet by the VLAN-ID. 21 to the network 21 via the core network 20.

[Operation (ISP → User)]
Next, an operation of transferring an Ethernet (registered trademark) packet from the ISP to the user will be described. The Ethernet (registered trademark) packet transferred from the ISP network 21 is already stored in the MAC address of the user acquired by a procedure such as arp (Address Resolution Protocol), the MAC address of the server used by the ISP to provide the service, and the ISP service based on the user contract. The corresponding VLAN-ID and data are included.

  The ISP network 21 transfers the Ethernet (registered trademark) packet to the core network 20. The core network 20 transfers the Ethernet (registered trademark) packet to the service distribution device 3 in which the user is accommodated based on the transfer table of the layer 2 switch in the core network 20.

  When the service distribution device 3 receives an Ethernet (registered trademark) packet from the core network 20, the transfer control unit 3-3 inputs the Ethernet (registered trademark) packet via the core network interface 3-6, and the Ethernet (registered trademark) is registered. The expansion tag is acquired from the destination MAC address of the (trademark) packet using the forwarding database 3-2. Further, the transfer control unit 3-3 compares the acquired expansion tag and VLAN-ID of the Ethernet (registered trademark) packet with the expansion tag and VLAN-ID set in the service access control list 3-5. Determine whether the correspondence is correct. If it is determined that the correspondence is correct, the first extension tag (the line information between the in-home terminal device 11 and the in-station terminal device 2 to which the Ethernet (registered trademark) packet is to be transferred) is transferred to the Ethernet (registered trademark) packet. ) And the second expansion tag (line information between the home terminal device 11 to which the Ethernet® packet is to be transferred and the service distribution device 3) is stored. The Ethernet packet is transferred to a predetermined intra-station terminal 2. If it is determined that the correspondence is not correct, the transfer control unit 3-3 discards the Ethernet (registered trademark) packet. In this case, the transfer control unit 3-3 reports the discard information of the Ethernet (registered trademark) packet to the management device 4 via the management device interface 3-7. The management device 4 records a log of discard information of the Ethernet (registered trademark) packet.

  Upon receipt of the Ethernet (registered trademark) packet from the service distribution device 3, the in-station terminal device 2 uses the first extension tag of the Ethernet (registered trademark) packet to the in-house terminal device 11 in which the user is accommodated. Transfer the (registered trademark) packet.

  When receiving the Ethernet (registered trademark) packet from the in-station terminal device 2, the in-home terminal device 11 deletes the first extension tag from the Ethernet (registered trademark) packet, and communicates with the communication terminal via the Ethernet (registered trademark) switch 12. The Ethernet (registered trademark) packet is transferred to 13. In this case, when the communication terminal 13 is configured to assign / delete the VLAN-ID used for identifying the ISP service, the in-home terminal device 11 changes the Ethernet (registered trademark) packet received from the in-station terminal device 2. Without being transferred to the communication terminal 13 as it is. On the other hand, when the communication terminal 13 does not assign / delete the VLAN-ID, the in-home terminal device 11 deletes the VLAN-ID from the Ethernet (registered trademark) packet received from the in-station terminal device 2, and The Ethernet (registered trademark) packet is transferred to the communication terminal 13.

  As described above, according to the embodiment of the present invention, when the Ethernet (registered trademark) packet is transferred from the user to the ISP, the Ethernet (registered trademark) packet to which the user assigns the VLAN-ID using the communication terminal 13 is used. To the in-home terminal device 11, the in-station terminal device 2 assigns a first extension tag to each line from the in-home terminal device 11, and the service distribution device 3 performs second to each line from the in-house terminal device 2. And an Ethernet (registered trademark) packet is transferred to the ISP network 21. When the Ethernet (registered trademark) packet is transferred from the ISP to the user, the service distribution device 3 uses the second extension tag to transfer the Ethernet (registered trademark) packet transferred from the ISP network 21 to the intra-station terminating device 2. Then, the in-station terminal device 2 uses the first extension tag to transfer to the in-home terminal device 11 so that the user receives an Ethernet (registered trademark) packet. As a result, an Ethernet (registered trademark) access service based on the Ethernet (registered trademark) technology can be realized without using a session control protocol such as PPPoE or IPSec. Therefore, the user can save the trouble of setting these session control protocols, and the access service provider can use the Ethernet (registered trademark) access service system with an inexpensive device that does not require termination of these session control protocols. Can be configured.

  Further, according to the embodiment of the present invention, the intra-station terminal device 2 gives the first extension tag to the Ethernet (registered trademark) packet sent from the user, and the service distribution device 3 uses the second extension tag. To manage these expansion tags. By using these extension tags, it is possible to specify a user who is a transfer destination of an Ethernet (registered trademark) packet transferred from the ISP network 21.

  Further, according to the embodiment of the present invention, the service distribution device 3 identifies the ISP network 21 based on the VLAN-ID, and transfers an Ethernet (registered trademark) packet to the ISP network 21. Thereby, the user can select an IPS service using VLAN-ID by IEEE802.1Q. In addition, since the transfer range of the Ethernet (registered trademark) packet can be limited for each ISP service, unnecessary transfer of the Ethernet (registered trademark) packet in the core network 20 can be suppressed.

  In addition, according to the embodiment of the present invention, the service distribution device 3 associates the VLAN-ID with the expansion tag based on the contract between the user and the access service provider prior to providing the ISP service. Are compared as the service access control list 3-5, the expansion tag and VLAN-ID of the Ethernet (registered trademark) packet 103 received from the user are compared with the expansion tag and VLAN-ID of the service access control list 3-5. If they match, the Ethernet (registered trademark) packet is transferred to the ISP network 21 indicated by the VLAN-ID. If they do not match, the Ethernet (registered trademark) packet is discarded. Thereby, the user can switch a plurality of ISP services. Further, the access service provider can manage the ISP service available to the user and can exclude access to the ISP network 21 outside the contract.

  The present invention has been described with reference to the embodiment. However, the above description is intended to help the understanding of the present invention, and does not limit the scope of the claims of the present invention. Accordingly, various modifications can be made without departing from the gist of the present invention, and can be appropriately changed within the scope of achieving the object of the present invention and producing effects.

  The in-home terminal device 11, in-station terminal device 2, service distribution device 3, and management device 4 are input to a volatile storage medium such as a CPU and a RAM, a non-volatile storage medium such as a ROM, a keyboard and a pointing device. You may make it each be comprised with the computer provided with the interface for communicating with an apparatus, the monitor apparatus which displays an image and data, and an external apparatus. In this case, each function of the in-home terminal device 11, the in-station terminal device 2, the service distribution device 3, and the management device 4 is realized by causing the CPU to execute a program describing the functions. These programs can also be stored and distributed in a storage medium such as a magnetic disk (floppy disk, hard disk, etc.), optical disk (CD-ROM, DVD, etc.), semiconductor memory, or the like.

It is a figure which shows the structural example of the Ethernet (trademark) access service system which concerns on one Embodiment of this invention. It is a figure which shows the format of the Ethernet (trademark) packet sent out from a household terminal device. It is a figure which shows the example of a format of the Ethernet (trademark) packet to which the 1st expansion tag was provided in the terminal apparatus in a station. It is a figure which shows the example of a format of the Ethernet (trademark) packet to which the 2nd expansion tag was provided in the service distribution apparatus. It is a figure which shows the example of the management table stored in the management apparatus. It is a functional structural example explaining a service distribution apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Service station 2, 2-1 to 2-j Intra-station terminal device 3 Service distribution device 3-1, 3-1-1, 3-1-2-3-1-j User interface 3-2 Forwarding database 3-3 Transfer control unit 3-4 Packet filter / service distribution unit 3-5 Service access control list 3-6 Core network interface 3-7 Management device interface 4 Management devices 10, 10-1, 10-2, 10-3 to 10- i User home 11, 11-1, 11-2, 11-3 to 11-i Home terminal device 12, 12-1, 12-2, 12-3 to 12-i Ethernet (registered trademark) switch 13, 13- 1, 13-2, 13-3 to 13-i Communication terminal 20 Core network 21, 21-1, 21-22 to 21-k ISP network 101 Ethernet with VLAN-ID Doo (R) packet 102 first extended tagged Ethernet packet 103 second extended tagged Ethernet packet

Claims (4)

Under a service providing system for realizing a communication service by a user network including a service network for a service provider to provide a predetermined communication service to a user, a core network connected to the service network, and a communication terminal operated by the user An access network system that performs packet transfer control between the user network and the core network,
Intra-station termination having means for receiving a packet transmitted from the user network, a means for attaching a first extension tag corresponding to the line number from the user network to the received received packet, and transmitting to the service distribution apparatus Device, means for assigning a second expansion tag corresponding to the line number from the intra-station terminal device, VLAN defined by IEEE 802.1Q included in the first and second expansion tags and the received packet -Means for managing ID correspondence; means for preliminarily storing an access service list in which the first and second expansion tags defined by the service provider are associated with VLAN-ID; Expansion tag, second expansion tag and VLAN-ID, first expansion tag in the service access list, second Comparing the extension tag and the VLAN-ID, if there is a match, a service distribution device having means for transmitting the received packet to the service network represented by the VLAN-ID, and if it does not match, means for discarding the received packet is provided. An access network system characterized by The access network system according to claim 1, wherein
The service distribution apparatus further includes means for deleting the first extension tag and the second extension tag of the received packet from the received packet when the received packet is transferred to the service network via the core network. An access network system characterized by the above. Under a service providing system for realizing a communication service by a user network including a service network for a service provider to provide a predetermined communication service to a user, a core network connected to the service network, and a communication terminal operated by the user A packet transfer method in an access network for performing packet transfer control between the user network and the core network,
A service distribution device provided in the access network receives a packet transmitted from the user network, and assigns a first extension tag corresponding to the line number from the user network to the received packet, and the service distribution device And the service distribution device assigns a second extension tag corresponding to the line number from the in-station terminal device to the received packet, and holds the first extension tag and the second tag previously held by the service provider, Compare with the access service list in which the VLAN-ID defined by IEEE802.1Q is made to correspond. If they match, the received packet is transmitted to the service network indicated by the VLAN-ID, and if it does not match, the received packet is discarded. A packet transfer method characterized by the above. The packet transfer method according to claim 3, wherein
When the received packet is transferred to the service network via the core network by the service distribution device, the first extension tag and the second extension tag of the received packet are deleted from the received packet. Packet transfer method.

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