JP2006311173A - Ip telephone system, user side device, and method for fixing position - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a user device for IP telephone applicable to 0AB-J number service, and to provide an IP telephone system including that user device. <P>SOLUTION: The user side device imparts an MAC address unique to a telephone, and outputs a VoIP based voice packet imparted with VLAN-ID of route information representative of a given line as a tag to the telephone. A host apparatus receiving the VoIP based voice packet has a table storing a predetermined MAC address assigned to each telephone and the VLAN-ID tag as a tag. The host apparatus detects whether the telephone is connected with a regular position or not by comparing and collating a tag from the telephone with a tag on the table. Since the tag of the VoIP packet includes route information, connection position of the telephone can be authenticated. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an IP telephone system, a user-side device, and a method for fixing a user-side device capable of making a call via an IP network (that is, an IP network).

  Recently, interest in IP telephone services with low call charges has increased, and IP telephone services are expected to spread in the future. Normally, a telephone number starting with “050” is used as a telephone number used for the IP telephone service, but a telephone number in the same format as a fixed telephone (generally called 0AB to J numbers) can also be used. An IP telephone service is also known. As described above, various restrictions are imposed on the IP telephone service using the 0AB to J numbers in order to maintain the same reliability as that of the conventional fixed telephone service. Due to these restrictions, the 0AB to J numbers are used. The spread of IP telephone service using Internet tends to be delayed.

  As one of the restrictions imposed on this type of 0AB to J numbers, it is required to associate the telephone number of a fixed telephone with the place of call. This is because in the case of a fixed telephone, it is necessary to call back in the case of an emergency call such as a police or a fire department and confirm the position of the fixed telephone.

  On the other hand, as is seen in Japanese Patent Application Laid-Open No. 2003-158553 (Patent Document 1), many IP telephone devices used for ordinary IP telephone services are integrated with a personal computer and a headset. Is converted into an IP address and connected to an IP network via a router. In other words, the IP telephone apparatus disclosed in Patent Document 1 is a communication apparatus that transmits and receives information to and from a peer IP telephone apparatus by a peer-to-peer method, a telephone number received by the communication apparatus, and an IP telephone apparatus. And a telephone number search device for collating with the telephone number of itself. As a result of the collation in the telephone number search device, only when the two match, the communication device returns the IP address of the IP phone device itself, and uses this IP address to make a call connection with the other party's IP phone device. Yes.

  As is clear from this, Patent Document 1 does not disclose anything about realizing an IP telephone service using 0AB to J numbers. Therefore, Patent Document 1 does not suggest anything about the necessity of fixing the telephone number of the telephone and the position of the telephone and the means therefor.

  Further, it has been proposed that a conventional system that can use a telephone number that is currently in use can accommodate domestic calls, mobile phones, international calls, etc., but leave a subscriber telephone line for emergency calls.

JP 2003-158553 A

  An IP telephone service that can reduce telephone charges is very attractive to users, and it is very convenient for users to provide 0AB to J number services that can use telephone numbers that are currently used. Therefore, the realization of the 0AB to J number service is considered to play a major role in the spread of the IP telephone service.

  However, the IP telephone device itself assigns an IP address to the IP telephone device in the same manner as a computer, and connection using the IP address is performed. This means that the IP telephone apparatus can be used regardless of which telephone line it is connected to. Therefore, the actual situation has not been proposed in the past to fix the position of each IP telephone apparatus, and it is considered only to leave a subscriber line for an emergency call.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a telephone user side device that can authenticate the position of a telephone and can cope with an emergency call.

  Another object of the present invention is to provide a telephone user-side device that recognizes the position of a telephone using an identifier indicating a connection path corresponding to the telephone.

  Another object of the present invention is to provide an IP telephone system capable of authenticating the position of a telephone using an identifier from a user side device.

  According to the first aspect of the present invention, a user-side device that makes a call via an IP network includes a terminal device to which a telephone can be connected, and the terminal device indicates a route assigned to the terminal device. An identifier is assigned, and the terminal device includes means for assigning a telephone identifier unique to the telephone, and both the route identifier and the telephone identifier are used for fixing the position of the terminal device. A user-side device is obtained.

  According to a second aspect of the present invention, the path identifier is a telephone VLAN-ID (hereinafter referred to as a VoIP VLAN-ID (Vertical Local Area Network-Identifier)) representing a path of a telephone connected to the terminal device. And the telephone identifier is a telephone VoIP MAC (Media Access Control) address.

  According to the third aspect of the present invention, there is obtained a user side device characterized in that the terminal device gives the VoIP MAC address as the telephone identifier.

  According to a fourth aspect of the present invention, there is provided a user side device characterized in that the terminal device has a function of assigning the VoIP VLAN-ID in addition to the VoIP MAC address.

  According to the fifth aspect of the present invention, in response to a call from the telephone, the VoIP VLAN-ID is assigned to a packet given from the terminal device, and a tag is formed together with the VoIP MAC address. It is possible to obtain a user side device characterized by having a CPE (Customer Premises Equipment).

  According to the sixth aspect of the present invention, there is provided a user side device characterized in that a service class (CoS) number representing a service class (CoS) of the telephone is also generated as a part of a tag.

  According to a seventh aspect of the present invention, there is provided a user side device characterized in that the CoS number is generated by the terminal device.

  According to an eighth aspect of the present invention, the terminal device has a configuration that can be connected to a computer in addition to the telephone, the computer being assigned a computer identifier different from the telephone, and a path identifier for the telephone. Thus, a user-side device is obtained in which a different service system route identifier is assigned.

  According to a ninth aspect of the present invention, the terminal device has a configuration that can be connected to a computer in addition to the telephone, and the computer is assigned a computer identifier different from the telephone, and the telephone Thus, a user side device is obtained in which the same service system route identifier as the route identifier is assigned.

  According to the tenth aspect of the present invention, in an IP telephone system for making a call via an IP network, a path identifier representing a predetermined path can be assigned to a telephone, and An IP telephone system comprising a user side device that can be assigned a unique telephone identifier and a host device that authenticates and fixes the location of the terminal device using the path identifier and the telephone identifier is obtained.

  According to an eleventh aspect of the present invention, the path identifier is a VoIP VLAN-ID representing a line to be connected to the telephone, and the telephone identifier is a VoIP MAC address. Is obtained.

  According to a twelfth aspect of the present invention, the host device accommodates a plurality of the user side devices, and the VoIP VLAN-ID and the VoIP MAC address from each of the user side devices are predetermined. Switch means having a table for determining whether or not the VoIP VLAN-ID and the VoIP MAC address match; and in the switch means, the VoIP VLAN-ID and the VoIP MAC address are the predetermined VoIP VLAN-ID and VoIP MAC address. In the case of the IP telephone system, an IP telephone system characterized by having a VoIP server for authenticating the telephone is obtained.

  According to the thirteenth aspect of the present invention, the switch means is connected when a mismatch between the VoIP VLAN-ID and the VoIP MAC address and the predetermined VoIP VLAN-ID and VoIP MAC address is detected. An IP telephone system having a service server different from the VoIP server can be obtained.

  According to a fourteenth aspect of the present invention, there is provided an IP telephone system characterized in that the service server does not perform authentication when a mismatch is detected by the switch means.

  According to the fifteenth aspect of the present invention, the host device accommodates a plurality of the user side devices, and receives a VoIP type packet including the VoIP VLAN-ID and the VoIP MAC address from each user side device. A switch that determines a route according to the VoIP packet, and a VoIP VLAN-ID and VoIP MAC address in the VoIP packet that match the predetermined VoIP VLAN-ID and VoIP MAC address. There is provided an IP telephone system comprising a table for determining whether or not, and having a separator for setting the route of the VoIP packet according to the determination result.

  According to a sixteenth aspect of the present invention, in the separator, when the VoIP VLAN-ID and the VoIP MAC address match the predetermined VoIP VLAN-ID and VoIP MAC address, An IP telephone system characterized in that is fixed.

  According to the seventeenth aspect of the present invention, there is provided an IP telephone system characterized in that authentication is not performed for the telephone whose mismatch is detected in the separator.

  According to an eighteenth aspect of the present invention, in a method for fixing the position of a telephone used in an IP telephone system that provides telephone service via an IP network, the terminal apparatus is connected to the terminal apparatus to which the telephone is connected. A route identifier representing the route assigned to the phone and a telephone identifier unique to the telephone are assigned, and the host device side fixes and authenticates the location of the terminal device using both the route identifier and the telephone identifier. Thus, a method for fixing the position of the telephone can be obtained.

  According to a nineteenth aspect of the present invention, the path identifier is a telephone VLAN-ID (hereinafter referred to as VoIP VLAN-ID (Vertical Local Area Network-Identifier)) representing the path of the terminal device, and the telephone identifier. Is a VoIP MAC (Media Access Control) address for a telephone, and a telephone position fixing method is obtained.

  According to a twentieth aspect of the present invention, there is provided a telephone position fixing method, wherein the VoIP MAC address given as the telephone identifier is given by the terminal device.

  According to the twenty-first aspect of the present invention, there is provided a user side device characterized in that, in addition to the VoIP MAC address, the VoIP VLAN-ID is also given by the terminal device.

  According to a twenty-second aspect of the present invention, the position fixing method for a telephone is characterized in that the position of the terminal device is fixed using a table for detecting a match and a mismatch between the path identifier and the telephone identifier. Is obtained.

  According to a twenty-third aspect of the present invention, there is provided a telephone position fixing method characterized in that a switch storing the table is provided on the host device side.

  According to a twenty-fourth aspect of the present invention, there is provided a telephone position fixing method comprising the separator having the table.

  According to the present invention, VoIP VLAN-ID is assigned to a VoIP packet as route information of a line assigned to a telephone, and a VoIP MAC address is assigned to the telephone, and both VoIP VLAN-ID and VoIP MAC address are assigned. By using it, it is possible to specify the connection position of the telephone and to obtain a user side device that can prevent impersonation of other users.

  Furthermore, in the present invention, a tag including the VoIP VLAN-ID is generated at the user side terminal, and the user terminal is configured by the VoIP MAC, VLAN-ID, user ID, and user password (PWD) at a device higher than the subscriber terminal. Fix the position of the device. In this configuration, since an existing device or the like can be used as a higher-level device, system changes can be minimized. As described above, the telephone connected to the terminal device whose position is fixed has an advantage that it can easily cope with the transmission using the 0AB to J numbers including the emergency telephone.

  FIG. 1 shows a schematic configuration of an IP telephone system 20 according to the first embodiment of the present invention. The IP telephone system 20 shown in FIG. 1 includes a subscriber accommodation device (CO) 22, a BAS (Broadband Access Server) 24, a switch 25, and a RADIUS (Remote Authentication Dial-In User Server) 26. A plurality of user devices (only two user devices 301 and 302 corresponding to users 1 and 2 are shown in FIG. 1) are connected to the subscriber accommodation device (CO) 22.

  The illustrated user-side device 301 includes a CPE (Customer Precision Equipment) 321 including a media converter (MC) and a terminal device 341 according to the present invention. The illustrated terminal device 341 includes both a PC 361 and a telephone 381. However, it may be configured to connect only the telephone 381.

  On the other hand, the CPE 322 including the MC and the terminal device 342 according to the present invention are also provided in the user side device 302, and the terminal device 342 is also configured to be connected to both the PC 362 and the telephone 382. Here, since each of the terminal devices 341 and 342 operates according to VoIP (Voice over Internet Protocol), it may be hereinafter referred to as VoIP-TA (Terminal Adapter) or abbreviated as VA (Voice Adapter). . Here, these terminal devices 341 and 342 may be provided to each user by a business operator, or may be purchased by the user himself / herself. As described above, each of the illustrated user-side devices 301 and 302 has a configuration that includes both CPE (Customer Premises Equipment) 321 and 322 and terminal devices 341 and 342.

  PCs 361 and 362 connected to the illustrated terminal devices 341 and 342 are assigned unique MAC (Media Access Control) addresses (here, MAC: A and MAC: C, respectively) by NIC (Network Interface Card). It is assumed that On the other hand, the MAC addresses are not assigned to the telephones 381 and 382 themselves.

  The MC of the CPE 321 connected to the terminal device 341 is connected to the subscriber accommodation device 22 via an optical cable, and the MC 322 connected to the terminal device 342 is also connected to the subscriber accommodation device 22 via an optical cable. In this relation, the illustrated system will be described as constituting a Fiber To The Home (FTTH) system. However, the present invention is not limited to this configuration, and can be applied to a DSL (Digital Subscriber Line) system connected by a metal cable, or to a system adopting a PON (Passive Optical Network) configuration. Is possible.

  Here, to the lines of the terminal devices 341 and 342 of the users 1 and 2, VLAN-ID: a and VLAN-ID: b common to the PC and the telephone are assigned as route information indicating connection routes specific to these terminal devices, respectively. These have functions as path identifiers. That is, in this embodiment, VLAN-ID: a and VLAN-ID: b are assigned as route identifiers representing the lines of the terminal devices 341 and 342, and the PCs 361 and 362 are assigned computer identifiers for identifying computers. MAC: A and MAC: C are assigned, respectively.

  Furthermore, when the terminal device 341 according to the present invention receives a call from the telephone 381, the terminal apparatus 341 detects a call from the telephone 381, and a packet (with a VoIP MAC address assigned as an identifier unique to the telephone 381, that is, a telephone identifier ( (Referred to as a VoIP packet). In this example, VoIP MAC: B is given by the terminal device 341 as a VoIP MAC address.

  Similarly, the terminal device 342 has a function of outputting a VoIP packet to which a telephone identifier (VoIP MAC: D) unique to the telephone 382 is attached in response to a call from the telephone 382.

  On the other hand, the illustrated terminal apparatuses 341 and 342 output the packets (service-related packets) assigned with MAC: A and MAC: C from the PCs 361 and 362, respectively, to the CPEs 321 and 322 as they are.

  As a result, the MAC addresses described above are assigned to the service-related packets and the VoIP-related packets given from the terminal devices 341 and 342 according to the present invention to the subscriber accommodation device (CO) 22 via the CPEs 321 and 322, respectively. Yes. The subscriber accommodation device (CO) 22 supplies a packet including PC MAC: A and VLAN-ID: a as a PC address to the switch 25 for the service-related packet from the PC 361 of the user 1, while the user 1 For one VoIP packet, a packet including VoIP MAC: B and VLAN-ID: a is output to the switch 25 as a VoIP address.

  Similarly, when the subscriber accommodation device (CO) 22 receives the service-related packet of the user 2, the subscriber accommodation device (CO) 22 outputs a packet including the PC MAC: C and VLAN-ID: b, while receiving the VoIP-based packet of the user 2. , A packet including VoIP MAC: D and VLAN-ID: b is output.

  The illustrated switch 25 is a layer 2 switch (L2SW) and includes first and second user tables as shown in Table 1 corresponding to users 1 and 2.

  Specifically, the first user table for user 1 is composed of a first PC table and a first VoIP table, and similarly, the second user table for user 2 is composed of a second PC table and a second VoIP table. Has been.

  Here, as shown in Table 1, the first PC table of the first user table stores PC MAC: A and VLAN-ID: a assigned to the first user 1 in advance. When these PC MAC: A and VLAN-ID: a match those received from the user side device 301, the output VLAN-ID assigned to the PC 361 of the first user 1 (the VLAN for the service VR 241 of the BAS 24). -ID) is stored, and when there is a discrepancy between the PC MAC: A, VLAN-ID: a and the one received from the user side device 301, the BAS24 service VR241 is used as the outgoing route. VLAN-ID is stored.

  On the other hand, as shown in Table 1, VoIP MAC: B and VLAN-ID: a of the first user 1 are stored in the first VoIP table of the first user table. Further, when the stored VoIP MAC: B, VLAN-ID: a matches the received one, the VoIP VLAN-ID assigned to the telephone 381 of the first user 1 is also stored in the first VoIP table. If a mismatch is detected, the VLAN-ID for the service system VR 241 of the BAS 24 is stored as the outgoing route.

  Similarly, as shown in Table 1, the second PC table of the second user table stores PC MAC: C and VLAN-ID: b pre-assigned as PC addresses to the PC 362 of the second user 2. Yes. Also, in Table 1, if the received PC address matches the stored one, the service VLAN to the service system VR 241 of the BAS 24 indicating the outgoing route of the switch 25 assigned to the PC 362 of the second user 2 is shown. -ID is stored in Table 1, and the service VLAN-ID to the service system VR 241 of the BAS 24 is stored as the outgoing route in the case of mismatch.

  On the other hand, the second VoIP table of the second user table stores the VoIP MAC: D and VLAN-ID: b of the second user 2. The VLAN-ID to the VR 242 of the BAS 24 is stored in Table 1 as the outgoing route of the switch 25 when the received VoIP address matches the VoIP MAC: D, VLAN-ID: b. In this case, the service VLAN to the service VR 241 of the BAS 24 is also stored as the outgoing route of the switch 25.

  In this state, after the PC 361 is activated and the ID and password (PWD) of the user 1 are transmitted from the terminal device 341, the packet is output from the PC 361 to the switch 25 via the terminal device 341 and the subscriber accommodation device 22. The operation in the case of failure will be described.

  In this case, when the packet output from the terminal device 341 has tags of PC MAC: A and VLAN-ID: a, the first PC table of the user 1 is searched. When the first PC table is searched, the tag added to the packet matches the PC MAC: A, VLAN-ID: a stored in the first PC table, and thus the outgoing route is represented from the first PC table. The packet is converted into a VLAN-ID, and the packet is output to the VR 241 of the BAS 24 via the service VLAN corresponding to the VLAN-ID. Thus, in the switch 25, a path from the terminal device 301 to the switch 25 is established.

  Subsequently, the VR 241 of the BAS 24 outputs an authentication request packet to the service server 261 of the RADIUS 26. In this case, since the ID and password (PWD) of the terminal device 341 are included in the authentication request packet, the service server 261 of the RADIUS 26 authenticates that the packet is from the PC 361 from these ID and PWD. Since the authentication operation in the RADIUS 26 is the same as the authentication operation in the conventional RADIUS 26, there is an advantage that the design change of the RADIUS 26 is not required in the illustrated example.

  Similarly, when the terminal device 341 is activated, an authentication request including the user ID and password (PWD) assigned to the terminal device 341 is output from the terminal device 341, and subsequently, the terminal device 341 is output from the telephone 381. The voice packet having the VoIP MAC: B and the VLAN-ID: a is given to the switch 25 via the subscriber accommodation device (CO) 22. In this case, the first VoIP table shown in Table 1 is searched, and in this example as well, the contents of the first VoIP table and the tag match, so the switch 25 determines that the call originates from the regular telephone set 381. As a result, the position of the telephone 381 is fixed by the switch 25. Next, the switch 25 refers to the first VoIP table, reads the VLAN-ID for VoIP indicating the outgoing route, and sends an authentication request packet including ID and PWD to the VR 242 for VoIP of the BAS 24 via the VLAN for VoIP. Output.

  As a result, the VoIP authentication request packet is given to the VoIP server 262 of the RADIUS 26, and the terminal device 341 is authenticated by the ID and PWD.

  As described above, in this embodiment, the position of the telephone set 381 of the terminal device 341 is fixed by the switch 25 using the MAC address (MAC: B) and the VLAN-ID: b, and the VoIP server 262 allows the terminal device 341 to be connected. Authentication / identification is performed using ID / PWD. In the above-described example, the VoIP server 262 distributes the IP address to the terminal device 341, and the terminal device 341 uses the distributed IP address to connect to the SIP (Session Initiation Protocol) server 263. After the connection with the SIP server 263, the telephone set 381 is ready to make a call using the 0AB to J numbers.

  The above-described operation is the same when the regular PC 362 and the telephone set 382 that are determined in advance are connected to the terminal device 342 of the user 2.

  On the other hand, it is assumed that the terminal device 341 of the user 1 different from the regular PC and telephone set for the user 2 is connected to the terminal device 342 provided at the position of the user 2. That is, a case where the user 1 impersonates the user 2 and connects at the position of the user 2 will be described.

  In this case, for example, the terminal device 341 connected to the position of the user 2 outputs PCMAC: A as it is when the PC 361 is connected, and has a function of assigning VoIP MAC: B when a telephone is connected. .

  Therefore, when the PC 361 is connected to the terminal device 341, a packet including PCMAC: A is supplied from the terminal device 341 to the subscriber accommodation device 22 via the MC 322 as a service-related packet.

  Upon receipt of this service-related packet, the subscriber accommodation device 22 provides the switch 25 with a packet including the VLAN-ID: b assigned to the terminal device 342 as a tag together with the MAC: A. That is, the service-related packet includes MAC: A as the PC address of the PC 361, and includes VLAN-ID: b assigned to the terminal device 342 as route information.

  The switch 25 searches the second PC table of the second user table shown in Table 1 by the received MAC: A and VLAN-ID: b. Since the MAC: C and VLAN-ID: b stored in the second user table are different from the received MAC: A and VLAN-ID: b, a tag mismatch is detected. As shown in Table 1, in the case of mismatch, the PC-table of the second user table is set with the VLAN-ID assigned to the service VLAN as its outgoing route. Therefore, as described above, when a mismatch occurs between the stored tag and the received tag, the service server 261 of the BAS 24 and the RADIUS 26 is connected through the service VLAN.

  The service server 261 detects and authenticates the connection of the PC 361 from the MAC: A. Thus, for the PCs 361 and 362, it is only necessary to detect the MAC address assigned to each PC and specify the PC, and it is not necessary to identify and authenticate the position of each PC.

  Next, a case where the terminal device 341 of the user 1 is connected instead of the terminal device 342 of the user 2 and a telephone is connected to the terminal device 341 will be described. In this case, since the terminal device 341 has a function of assigning VoIP MAC: B to the telephone as a MAC address, a packet including the VoIP MAC: B is output from the terminal device 341 to the subscriber accommodation device 22. The The subscriber accommodation device (CO) 22 outputs a VoIP packet including MAC: B and VoIP VLAN-ID: b to the switch 25.

  The switch 25 stores the VoIP MAC: D and VLAN-ID: b stored in advance in the second VoIP table of the second user 2 shown in Table 1, and the received VoIP MAC: B and VLAN-ID: b, respectively. Compare and detect VoIP MAC address mismatch. As described above, when the switch 25 detects the mismatch of the VoIP MAC address in the VoIP system packet, the service system VLAN-ID is read from the second VoIP table, and the VoIP system is transmitted through the VLAN indicated by the service system VLAN-ID. The authentication request is output to the service server 261 of the RADIUS 26 via the VR 241 of the BAS 24. In other words, if a tag mismatch is detected by the switch 25, the terminal device 341 connected to the position of the user 2 is not connected to the VoIP server 262.

  When the service server 261 detects the user ID / PWD accompanying the VoIP authentication request packet, the service server 261 performs authentication. However, since the service server 261 does not match the user 2, the service server 261 fails in user authentication. As a result, the service server 261 does not give out an IP address to the user 2 when a mismatch is detected.

  Therefore, in the IP telephone system shown in FIG. 1, even if the terminal device is to be used in a device other than the terminal device assigned to the terminal device, the service server 261 of the RADIUS 26 fails to authenticate the VoIP packet. As described above, when the user 1 or 2 is connected to a different position, the RADIUS 26 fails to authenticate the VoIP telephone, and as a result, does not give out the IP address to the telephone and rejects the telephone connection. In other words, the 0AB to J number service cannot be received unless the telephone is connected to the terminal device at the position defined for the telephone.

  As described above, in the embodiment shown in FIG. 1, the switch 25 has a combination of VLAN-ID and MAC address defined in the first and second VoIP tables and a different combination of VLAN-ID and MAC address. When a packet is input, it is necessary to replace the VLAN-ID assigned to the packet with the VLAN-ID instructing the service server 261 and output the packet to the BAS 24 via the service VLAN. In other words, in the embodiment shown in FIG. 1, as described above, the switch 25 having the function of changing the VLAN-ID is necessary. This means that the conventionally used switch is not used as it is. It means you can't.

  Referring to FIG. 2, an IP telephone system according to another embodiment of the present invention can use a conventionally used layer 2 switch (L2SW) as a switch 25, and can also use the entire user ( Here, a case where a common VLAN-ID is assigned to the users 1 and 2) (VLAN-ID: X) will be described. Specifically, the terminal device 341 provided in the user 1 has a function of outputting the MAC address (MAC: A) of the PC 361 as it is when the PC 361 is connected to the terminal device 341. In addition, it has a function of assigning VLAN-ID: X as the VLAN-ID of the PC 361.

  On the other hand, the terminal device 341 of the user 1 has a function of assigning both VoIP MAC: B and VLAN-ID: Y when the telephone set 381 is connected to the terminal device 341.

  On the other hand, when the PC 362 is connected to the terminal device 342, the terminal device 342 provided to the user 2 outputs a MAC address (MAC: C) of the PC 362 as it is and a function to assign VLAN-ID: X. It has. In other words, the terminal devices 341 and 342 of the users 1 and 2 shown in the figure assign a common VLAN-ID to the connected PC.

  Further, when a telephone 382 is connected to the terminal device 342 of the user 2, the terminal device 342 has a function of assigning VoIP MAC: D and VLAN-ID: Z to the telephone 382. In this embodiment, the terminal devices 341 and 342 of the users 1 and 2 give different VLAN-IDs: Y, Z to the telephones, and also give unique VoIP MACs: B, D. Here, it is assumed that VoIP VLAN-ID: Y and VLAN-ID: Z indicate a specific outgoing route of the existing L2SW (switch) 25 assigned to the telephones 381 and 382 by the VLAN.

  The illustrated switch 25 outputs a service-related packet including the service-related VLAN-ID: X on the service VLAN, and on the other hand, a VoIP-based voice packet including the VoIP VLAN-ID: Y and Z on the VoIP VLAN. Is output. The VoIP voice packet also includes VoIP MACs B and D assigned by the terminal devices 341 and 342.

  In this way, when packets having different VoIP VLAN-IDs: Y and Z are output from the existing layer 2 switch (L2SW) 25, these different VoIP VLAN-IDs: Y and Z are used as these VoIP voice packets. It is necessary to guide to the corresponding VoIP server 262.

  In the illustrated embodiment, a separator 50 is provided between the switch 25 and the BAS 24, and the separator 50 can receive VoIP voice packets from the users 1 and 2 output from the switch 25. The separator 50 provided at the position of the route is provided with a MAC / VLAN table related to the VoIP packets of the users 1 and 2. That is, the MAC / VLAN table in which the VLAN-IDs of the VoIP tables of the users 1 and 2 in Table 1 are respectively replaced with Y and Z is set in the separator 50.

  That is, the VoIP table of the user 1 stores the combination of the VoIP MAC: B and VLAN-ID: Y of the terminal device 341 and the relationship between the VLAN-ID between the separator 50 and the VR 242 of the BAS 24 corresponding thereto. On the other hand, the 2 VoIP table of the user 2 stores a combination of VoIP MAC: D and VLAN-ID: Z of the terminal device 342 and a VLAN-ID between the separator 50 and the VR 242 of the BAS 24 corresponding to this combination.

  Therefore, if the tags of the VoIP packets received from the terminal devices 341 and 342 match the VoIP MAC addresses and VLAN-IDs of the terminal devices 341 and 342 stored in the VoIP tables of the users 1 and 2, the 2 VoIP of the users 1 and 2 A VLAN corresponding to the VLAN-ID stored in the table is selected, and connected to the VR 242 of the BAS 24 via the selected VLAN. Thus, in this embodiment, the positions of the telephones 381 and 381 connected to the terminal devices 341 and 342 are fixed by the separator 50 using the MAC / VLAN-ID.

  The VR 242 of the BAS 24 connected via the separator 50 outputs a VoIP authentication request packet including the ID / PWD of the terminal device to the VoIP server 262 of the RADIUS 26 to the VoIP server 262.

  The VoIP server 262 authenticates the user ID and password (PWD) in the same manner as in FIG. When the ID / PWD of the authentication request packet matches the user ID and password (PWD) determined for each user, the IP address is paid out to the terminal device. On the other hand, when a mismatch is detected in the VoIP server 262 of the RADIUS 26, the authentication of the VoIP server 262 fails and no IP address is issued.

  In the above-described embodiment, the VoIP VLAN-ID of the VoIP packet functions as a path identifier as connection information representing the circuit path of the VoIP packet, while the terminal identification information (that is, the terminal) in which the VoIP MAC address represents the terminal device It can be seen that it has a function as an identifier).

  In the above-described form, the telephone connected to each terminal device that has been fixed and authenticated is in a state where it is possible to make a call from 0AB to J numbers in response to the IP address distributed to the telephone. become.

  As described above, in the embodiment shown in FIG. 2, the position of the telephone can be authenticated and fixed only by combining the existing layer 2 switch 25 with the separator 50. Therefore, the IP telephone system shown in FIG. 2 has an advantage that it is not necessary to newly develop the switch 25. Also in RADIUS 26, authentication can be performed with minimal changes in settings.

  Here, a case where the terminal device 341 of the user 1 is connected instead of the terminal device 342 of the user 2 will be described. In this case, even if the PC 361 or 362 is connected to the terminal device 341, it is not necessary to specify the position of each PC. Therefore, the terminal device 341 outputs the MAC address and VLAN-ID of the PC as it is for the service-related packet.

  On the other hand, when the terminal device 341 of the user 1 is connected as the terminal device of the user 2, the terminal device 341 is different from the VoIP MAC: D and VLAN-ID: Z of the terminal device 342 with respect to the telephone 382. B and VLAN-ID: Y will be assigned. In this way, when a VoIP MAC and VLAN-ID different from the normal VoIP MAC and VLAN-ID are given to the subscriber accommodation device (CO) 22, the subscriber accommodation device 22 performs the VLAN filter operation, and the set VLAN As a result, even if a terminal device different from the regular terminal device is connected to the user 2, connection to a device higher than the subscriber accommodation device 22 is rejected.

  On the other hand, when the separator 50 detects a mismatch between the VoIP MAC address and the VoIP VLAN-ID for some reason, the separator 50 rejects the connection to the host device and discards the packet. In any case, in the illustrated example, the position of the telephone connected to the terminal devices 341 and 342 can be fixed only by providing only the separator 50 in the existing system.

  Note that each of the terminal devices 341 and 342 shown in the figure transmits a normal Ethernet (registered trademark) packet with priority given to voice.

  With reference to FIG. 3, an example of a VLAN-ID assignment method applicable to FIGS. 1 and 2 will be described. First, the NIC (Network Interface Card) provided in the PCs 361 and 362 of each user is assigned a MAC (Media Access Control) address unique to the NIC. For this reason, the packets of the PCs 361 and 362 include data As a link layer (layer 2) header, a MAC (Media Access Control) address is written. Here, it is assumed that MAC: A and MAC: C are assigned to the PCs 361 and 362 as MAC addresses, respectively.

  Furthermore, in the example shown in FIG. 3, CPE (Customer Precision Equipment) 301 and 302 are provided in addition to the terminal devices (VoIP-TA) 341 and 342 as user side devices. Similar to FIGS. 1 and 2, a PC 361 and a telephone set 381 are connected to the terminal device 341, while a PC 362 and a telephone set 382 are connected to the terminal device (VoIP-TA) 342. Hereinafter, the illustrated terminal apparatuses 341 and 342 are described as having the same configuration, but both the terminal apparatuses 341 and 342 are not necessarily required to have the same configuration. The terminal device 341 and the CPE 301, and the terminal device 342 and the CPE 302 may be integrated and placed in the homes of the users 1 and 2. The illustrated CPEs 301 and 302 and the subscriber accommodation device 20 are connected by a medium such as an optical cable or a metal cable.

  The illustrated terminal apparatuses 341 and 342 have a function of outputting a VoIP packet from the telephones 381 and 382 in preference to a packet from the service system, that is, the PCs 361 and 362, and in this example, Ethernet (registered trademark) is provided. ) Output in packet format. The terminal devices 341 and 342 output the voice given from the telephones 381 and 382 as VoIP packets.

  In this case, the terminal device 341 has a function of assigning MAC: B as the MAC address of the telephone 381. As a result, the terminal device 341 transmits a packet having MAC: B. On the other hand, the terminal device 342 has a function of outputting a packet having a MAC address (MAC: D) assigned to the telephone 382.

  On the other hand, the terminal devices 341 and 342 send packets having the MAC addresses of MAC: A and MAC: C from the PCs 361 and 362 to the upper CPEs 301 and 302 as they are. In this way, by assigning MAC addresses to the telephones 381 and 382 in the terminal apparatuses 341 and 342, the host apparatus can detect whether the packet is from either the PC or the telephone.

  The CPE 301 connected to the terminal device 341 includes a MAC address detecting unit 401 that receives MAC: A and MAC: B and detects these MAC: A and MAC: B. The MAC address detection unit 401 has a function of detecting whether the packet is received from the PC 361 or the telephone 381, and adding a tag corresponding to the detected PC 361 or telephone 381.

  Similarly, the CPE 302 is also provided with a MAC address detection unit 402, and the MAC address detection unit 402 detects MAC: C and MAC: D, thereby detecting a packet corresponding to the detection result. It has a function to grant.

  In the illustrated example, the MAC address detection unit 401 assigns a VLAN-ID: X assigned to a service-related packet to the packet, and assigns a CoS number 1 indicating the service class (CoS) of the packet. ing. As a result, as shown in FIG. 3, the service packet is given a tag consisting of CoS: 1, VLAN-ID: X, MAC: A.

  Further, the MAC address detection unit 401 assigns the VLAN-ID: Y assigned to the VoIP packet, and also gives the VoIP packet a CoS number (CoS: 7) indicating the service class of the VoIP packet. As a result, a tag composed of CoS: 7, VLAN-ID: Y, and MAC: B is formed in the VoIP packet as shown in FIG.

  In this way, a packet including a tag consisting of a service class (CoS) number, VLAN-ID, and MAC: A is given to the subscriber accommodation device (CO) 20, and the subscriber accommodation device 20 The data is transmitted to the BAS 24 via the VLAN corresponding to the VoIP packet, and the telephone 381 is authenticated and fixed in the same manner as in FIG. 1 or FIG.

  The MAC address detection unit 402 of the CPE 302 also performs the same operation as the MAC address detection unit 401, and the service packet from the PC 362 includes a tag made up of CoS: 1, VLAN-ID: X, and MAC: C. Is sent to the subscriber accommodation device (CO) 20, while the VoIP packet of the telephone 382 is assigned a tag consisting of CoS: 7, VLAN-ID: Z, and MAC: D, Is transmitted to the person accommodation device 20. Packets having these tags are also processed in the same manner as in FIGS. 1 and 3, and the telephone 382 is authenticated and fixed.

  In this case, since the CPEs 301 and 302 distribute service packets and VoIP packets by VLAN-ID, the VLAN-ID included in the tag of each packet has a function as packet route information. ing.

  When the tag addition method shown in FIG. 3 is applied to FIG. 1, the MAC address detection unit 401 of the CPE 301 assigns VLAN-ID: a instead of the VLAN-ID: X and Y shown in FIG. What is necessary is just to comprise. The MAC address detection unit 402 of the CPE 302 may be configured to assign a common VLAN-ID: b to the service system and the VoIP system instead of the VLAN-IDs: X and Z.

  When the tag addition method shown in FIG. 3 is applied to the IP telephone system shown in FIG. 2, the terminal devices 341 and 342 and the CPEs 301 and 302 shown in FIG. 3 can be used as they are. . That is, a common VLAN-ID: X is assigned to service-related packets from the terminal devices 341 and 342, and VoIP VLAN-ID: Y and Z are assigned to VoIP-related packets from the terminal devices 341 and 342, respectively. The CPEs 301 and 302 to be assigned can be used as they are.

  With reference to FIG. 4, another configuration example of the tagging method that can be applied to FIGS. 1 and 2 will be described. In this example, a configuration example in which a common VLAN-ID is assigned to all users in a service-related packet is shown. In this example, the service-related packets are transmitted from the terminal devices 341 and 342 to the VLAN- ID: X shall be given. On the other hand, it is assumed that VLAN-ID: Y is also commonly assigned to all users by the terminal devices 341 and 342 in the VoIP packet, and VLAN-D: Y is different from VLAN-ID: X. To do. The terminal devices 361 and 362 output the VoIP voice packet in preference to the service packet in the same manner as the terminal devices 341 and 342 shown in FIG.

  A PC 361 and a telephone set 381 are connected to the terminal device 341 shown in FIG. 4. As in the case of FIG. 3, a packet including the MAC address of MAC: A is given from the PC 361. Voice does not contain a MAC address. Further, a PC 362 and a telephone 382 are connected to the terminal device 342, and a packet including MAC: C is given from the PC 362.

  In this configuration example, common VLAN-IDs: X and Y are assigned to the terminal devices 341 and 342. In this case, the terminal device 341 includes a tag assignment unit 451. The tag assignment unit 451 may determine whether the PC 361 and the telephone 381 are physically connected by detecting the physical connection position of the PC 361 and the telephone 381, or the presence / absence of a MAC address (MAC: A) or the presence / absence of a packet. By detecting this, it may be configured to identify whether the packet is a service packet or VoIP voice. When it is detected that the access is from the PC 361, the tag assigning unit 451 assigns VLAN-ID: X and CoS: 1 assigned to the service system to the packet, and as shown in FIG. 4, CoS: 1 , VLAN-ID: X and MAC: A are generated.

  On the other hand, when a VoIP analog voice signal from the telephone 381 is given, the tag assigning unit 51 includes a VoIP system including a tag consisting of CoS: 7, VLAN-ID: Y, and MAC: B defined for the VoIP system. Generate a packet.

  Similarly, the terminal device 342 connected to the PC 362 and the telephone set 382 also includes a tag assigning unit 452, and in the tag assigning unit 452, as shown in FIG. 4, CoS: 1, VLAN-ID: X, MAC: C A service type packet including a tag consisting of is generated, while a VoIP type packet including a tag consisting of Cos: 7, VLAN-ID: Y, and MAC: D is generated.

  As described above, the service-related packets generated from the terminal devices 341 and 342 include a common VLAN-ID: X, but since the MAC addresses are different, services from both the terminal devices 341 and 342 are used. Identification of the system packet is easy.

  Similarly, VoIP voice packets generated from the terminal devices 341 and 342 include a common VLAN-ID: Y and have different MAC addresses (MAC: B, MAC: C). VoIP packets from the devices 341 and 342 can be identified. However, since VLAN-ID: Y as route information or route identifier is common, the telephones 381 and 382 cannot be individually identified and authenticated by the VLAN-ID: Y. In addition, since it is not necessary to specify the positions of the PCs 361 and 362 for the service-related packet, there is no problem even if the VLAN-ID: X common to each other is included in the packet.

  In consideration of the above points, in the example shown in FIG. 4, VLAN-ID: Y from the terminal device 341 is changed to VLAN-ID: L unique to the terminal device 341 in the CPE 301 connected to the terminal device 341. A tag changing unit 471 for changing is provided. In this tag changing unit 471, MAC: B and CoS: 7 are not changed, while the service-related packet passes as it is.

  On the other hand, the CPE 302 also includes a tag changing unit 472 that changes VLAN-ID: Y given from the terminal device 342 to VLAN-ID: N unique to the terminal device 342. Here, by making VLAN-ID: N and VLAN-ID: L different from each other, the positions of the telephones 381 and 382 can be individually identified and authenticated.

  The subscriber accommodation device 20 connected to the CPEs 301 and 302 receives the packet including the tag and outputs it to the switch 50. More specifically, in the example of FIG. 1, the subscriber accommodation device (CO) 22 distributes the packet to the host device according to the MAC / VLAN table shown in Table 1 in the switch 25, and in the example of FIG. The MAC / VLAN table is referred to by the separator 50, and if they do not match, the packet is discarded without connecting to the upper level.

  4 is applied to FIG. 1, the service-related packet from the terminal apparatus 341 is assigned VLAN-ID as a VLAN-ID, and a is assigned as VoIP VLAN-ID of the VoIP packet. , CPE 301 may be configured to give a instead of L. Further, the CPE 302 may be configured such that b is given instead of X as the VLAN-ID of the service-related packet from the terminal device 342 and b is given instead of N as the VoIP VLAN-ID of the VoIP-based packet. .

  When the tag addition method shown in FIG. 4 is applied to FIG. 2, the VLAN changer 471 of the CPE 301 outputs VLAN-ID: Y as it is for the VoIP packet, while the tag change of the CPE 302 is changed. In the unit 472, the VoIP VLAN-ID: Y may be changed to Z.

  With reference to FIG. 5, another configuration example for forming a tag will be described. This configuration example is a case where a VLAN-ID common to users is set in a service packet, and a different VLAN-ID is set for each user in a VoIP packet. Also in this example, the terminal devices 341 and 342 output the VoIP voice packet with priority over the service packet.

  For this reason, when the terminal device 341 shown in FIG. 5 packetizes the voice from the telephone set 381, the terminal apparatus 341 gives a MAC address (MAC: B) unique to the telephone set 381 and sets the VLAN defined for the terminal apparatus 341. A VLAN-ID for identification (VLAN-ID: Y) is assigned together with CoS: 7 and has a first tag adding unit 521 that forms a tag. On the other hand, the CPE 301 connected to the terminal device 341 generates a VLAN-ID (VLAN-ID: X) that identifies the VLAN for the service packet in order to connect to the VLAN set in common for the service packet. There is a need.

  Therefore, the illustrated CPE 301 includes a second tag adding unit 541 that sets VLAN-ID: X and CoS: 1 as tags. In this case, since the second tag adding unit 541 passes the MAC: A attached to the packet from the terminal device 341 as it is, the subscriber accommodation device 20 is provided with CoS: 1, VLAN as shown in FIG. -A service packet including a tag consisting of ID: X and MAC: A is output from the CPE 301 to the subscriber accommodation device 20, and transmitted from the subscriber accommodation device 20 onto the VLAN-ID: X set in the service packet. Is done.

  On the other hand, the tag attached to the VoIP voice packet is output from the CPE 301 to the subscriber accommodation device 20 as it is. In this example, a VoIP voice packet including VLAN-ID: Y is output on the VLAN identified by the VLAN-ID: Y.

  Similarly, the terminal device 342 connected to the PC 362 and the telephone 382 has a first tag adding unit 522, and VLAN-ID: Z and MAC: set in the terminal device 342 by the first tag adding unit 522. Generate D and form a tag with CoS: 7. The VoIP voice packet including the tag passes through the CPE 302 and is directly sent to the subscriber accommodation device 20 and is output on the VLAN designated by the VLAN-ID: Z. On the other hand, the service-related packet including MAC: C passes through the terminal device 342 and is supplied to the second tag adding unit 542 of the CPE 302.

  The second tag addition unit 542 assigns a common VLAN-ID: X to service-related packets and also assigns CoS: 1, thereby forming a tag together with MAC: C. A service packet including such a tag is output on VLAN: X common to the service packets.

  When the tag assignment method shown in FIG. 5 is applied to the IP telephone system shown in FIG. 1, the terminal device 341 only has to assign a as a packet VLAN-ID and a VoIP VLAN-ID. The first tag adding unit 521 and the second adding unit 541 may adopt a configuration in which VLAN-ID: a is assigned instead of VLAN-ID: X, Y. On the other hand, on the terminal device 342 side, b may be assigned as the packet VLAN-ID and the VoIP VLAN-ID. Therefore, the first tag adding unit 522 and the second tag adding unit 542 have VLAN-IDs: X and Z Instead of this, it is only necessary to provide a configuration for providing VLAN-ID: b.

  Since these service-related packets and VoIP-based voice packets output on the VLAN are processed by the method described with reference to FIGS. 1 and 2, description thereof is omitted here.

  In FIGS. 3 to 5, the tag addition method of assigning tags using the CPEs 301 and 302 in addition to the terminal devices 341 and 342 has been described. However, the present invention is not limited to this, and the terminal devices 341, A desired tag can be formed by 342 alone.

  Referring to FIG. 6, a common VLAN-ID: X is assigned to the service packet and VoIP packet output from the terminal device 341, while the service packet and VoIP packet output from the terminal device 342 are provided. In the figure, a common VLAN-ID: Y is given. That is, the illustrated example is a case where the VLAN-ID is changed on a subscriber basis. In this case, the terminal device 341 is connected to the PC 361 and the telephone set 381, and a packet having MAC: A is input from the PC 361, while voice is input from the telephone set 381.

  The tag adding unit 601 detects MAC: A, passes the MAC: A to the packet from the PC 361, adds CoS: 1, and uses VLAN− as the route information assigned to the terminal device 341. ID: X is assigned. On the other hand, when receiving voice input from the telephone 381, the tag assigning unit 601 generates a VoIP packet to which MAC: B, VLAN-ID: X, and CoS value: 7 are assigned as tags.

  A common VLAN-ID: Y is assigned to the service packet and the VoIP packet output from the terminal device 342. For this reason, the tag assigning unit 602 passes the MAC: C of the packet from the PC 362, assigns CoS: 1, and adds VLAN-ID: Y as route information. Further, the tag assigning unit 602 assigns MAC: D and VLAN-ID: Y to the voice from the telephone 382 and assigns CoS: 7.

  Thus, in the configuration example shown in FIG. 6, a common VLAN-ID is assigned to each terminal device 341. For this reason, in the host device, it is necessary to identify the service packet and the VoIP packet for each user. However, such identification of a packet can be easily performed by identifying a MAC address included in the packet. For example, the subscriber accommodation device and / or the switch 25 can identify the service packet and the VoIP packet using the MAC address and the VLAN-ID, and distribute the service packet and the VoIP voice packet. .

  The tagging system shown in FIG. 6 can be applied to the IP telephone system shown in FIG.

  As described above, the IP telephone system according to the present invention provides a device such as a telephone connected to the terminal device by providing a device on the user terminal side that can assign VLAN-ID and MAC: ID to the voice packet. Since the position can be identified and authenticated, the position of a device such as a telephone can be recognized and fixed. As a result, a 0AB to J number service is provided that can recognize the position even when a call is made to an emergency telephone number. be able to.

It is a block diagram which shows the structure of the IP telephone system which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the IP telephone system which concerns on other embodiment of this invention. FIG. 3 is a block diagram showing an example of a tagging method applicable to the IP telephone system of FIGS. 1 and 2. It is a block diagram which shows the other structural example of a tag provision system. It is a block diagram which shows the other structural example of a tag provision system. It is a block diagram which shows another structural example of a tag provision system.

Explanation of symbols

20 IP telephone system 22 Subscriber accommodation equipment (CO)
24 BAS
241,242 VR
25 Switch 26 RADIUS
261 Service server 262 VoIP server 301, 302 CPE
321, 322 MC
341, 342 Terminal equipment (VoIP-TA)
361, 362 PC
381, 382 Telephone

Claims (24)

  A user-side device that performs a call via an IP network includes a terminal device that can be connected to a telephone. The terminal device is assigned a route identifier that represents a route assigned to the terminal device. A user-side device comprising means for assigning a telephone identifier unique to the telephone, wherein both the path identifier and the telephone identifier are used for fixing the position of the terminal device.   2. The telephone set identifier according to claim 1, wherein the path identifier is a telephone VLAN-ID (hereinafter referred to as a VoIP VLAN-ID (Vertical Local Area Network-Identifier)) representing a path of a telephone connected to the terminal device. A user-side device, which is a VoIP MAC (Media Access Control) address for a telephone.   3. The user side device according to claim 2, wherein the terminal device gives the VoIP MAC address as the telephone identifier.   3. The user side device according to claim 2, wherein the terminal device has a function of assigning the VoIP VLAN-ID in addition to the VoIP MAC address.   3. The CPE (Customer Precision Equipment) according to claim 2, wherein a VoIP VLAN-ID is assigned to a packet given from the terminal device in response to a call from the telephone, and a tag is formed together with the VoIP MAC address. A user side device characterized by comprising:   6. The user apparatus according to claim 2, wherein a service class (CoS) number representing a service class (CoS) of the telephone is also generated as a part of the tag.   7. The user side device according to claim 6, wherein the CoS number is generated by the terminal device.   The terminal device according to any one of claims 1 to 7, wherein the terminal device includes a configuration that can be connected to a computer in addition to the telephone, and the computer is assigned a computer identifier different from the telephone, Are assigned with different service system route identifiers.   In any one of Claims 1-7, the said terminal device is provided with the structure which can be connected with a computer besides the said telephone, The computer identifier different from the said telephone is provided to the said computer, A user-side device, characterized in that the same service system route identifier as the route identifier is assigned.   In an IP telephone system for making a call over an IP network, a user can assign a route identifier representing a predetermined route to a telephone and can assign a unique telephone identifier to the telephone. An IP telephone system comprising: a device; and a host device that authenticates and fixes the position of the terminal device using the route identifier and the telephone identifier.   11. The IP telephone system according to claim 10, wherein the route identifier is a VoIP VLAN-ID representing a line to which the telephone is connected, and the telephone identifier is a VoIP MAC address.   In Claim 11, the said high-order apparatus accommodates the said user side apparatus in multiple numbers, and the said VoIP VLAN-ID and the said VoIP MAC address from each said user side apparatus are set predetermined VoIP VLAN-ID and VoIP Switch means having a table for determining whether or not it matches the MAC address, and in the switch means, the VoIP VLAN-ID and the VoIP MAC address match the predetermined VoIP VLAN-ID and VoIP MAC address And an VoIP server for authenticating the telephone.   13. The VoIP server according to claim 12, wherein the switch means is connected when a mismatch between the VoIP VLAN-ID and the VoIP MAC address and the predetermined VoIP VLAN-ID and VoIP MAC address is detected. An IP telephone system comprising different service servers.   14. The IP telephone system according to claim 13, wherein the service server does not perform authentication when a mismatch is detected by the switch means.   12. The host device according to claim 11, wherein the host device receives a plurality of the user side devices, receives a VoIP packet including the VoIP VLAN-ID and the VoIP MAC address from each user side device, and receives the VoIP packet. A switch that determines a corresponding route and a VoIP VLAN-ID and VoIP MAC address that are arranged in the determined route and that are in the determined route determine whether or not the VoIP VLAN-ID and VoIP MAC address match a predetermined VoIP VLAN-ID. An IP telephone system comprising a table and a separator for setting a route of the VoIP packet according to a determination result.   16. The position of the telephone is fixed by the separator when the VoIP VLAN-ID and the VoIP MAC address match the predetermined VoIP VLAN-ID and VoIP MAC address in the separator. IP phone system.   The IP telephone system according to claim 16, wherein authentication is not performed for the telephone in which a mismatch is detected in the separator.   In a method for fixing the position of a telephone used in an IP telephone system that provides telephone service via an IP network, a path identifier that represents a path assigned to the terminal apparatus to a terminal apparatus to which the telephone is connected; A telephone position fixing method comprising: assigning a telephone identifier unique to a telephone, and fixing and authenticating the position of the terminal device on a higher-level apparatus side using both the path identifier and the telephone identifier.   19. The telephone identifier according to claim 18, wherein the path identifier is a telephone VLAN-ID (hereinafter referred to as a VoIP VLAN-ID (Vertical Local Area Network-Identifier)) representing the path of the terminal device, and the telephone identifier is a telephone VoIP MAC ( A method for fixing the position of a telephone, wherein the address is a Media Access Control) address.   20. The telephone position fixing method according to claim 19, wherein the VoIP MAC address given as the telephone identifier is given by the terminal device.   21. The user side device according to claim 20, wherein, in addition to the VoIP MAC address, the VoIP VLAN-ID is also given by the terminal device.   21. The method for fixing a position of a telephone according to claim 18, wherein the position of the terminal device is fixed using a table for detecting a match and a mismatch between the path identifier and the telephone identifier.   23. The telephone position fixing method according to claim 22, further comprising: a switch storing the table on the host device side. The method for fixing a position of a telephone according to claim 22, further comprising a separator provided with the table.

Images