JP5105074B2 - IP phone system - Google Patents

Description

  The present invention relates to an IP telephone system, and more particularly to an IP telephone system that controls transmission / reception of RTP (Real Time Transport Protocol) packets under the control of a SIP server.

  As a conventional IP telephone system of this type, every time an IP telephone terminal is registered in a SIP server, the address conversion information of the IP telephone terminal is registered, and the SIP server notifies the address conversion apparatus of the address conversion information for each call. The outgoing IP telephone terminal and the incoming IP telephone terminal exchange RTP port numbers with each other, so that RTP packets can be transmitted and received at the RTP port, and the adverse effect of statically setting the address translation pattern is reduced. An example of exclusion is known (see, for example, Patent Document 1).

  In addition, when the transmission-side termination device and the reception-side termination device are connected by a plurality of relay devices and lines, and the relay device receives a frame from the termination device, the traffic of the transmission-destination network is transmitted each time the frame is transmitted to the transmission-destination network. When the amount exceeds the predetermined value, the traffic volume is dynamically distributed by rewriting the media call control address and network address of the own device and selecting another relay device and line. Examples are also known (see, for example, Patent Document 2).

JP-A-2005-72817 (pages 6-7, FIG. 1) Japanese Patent Laid-Open No. 07-235939 (pages 4-6, FIG. 1)

  However, in the IP telephone system described in Patent Document 1 described above, since the RTP packet transmission / reception is performed between the originating IP telephone terminal and the incoming IP telephone terminal, the route through which the RTP packet flows cannot be specified. When the traffic of RTP packets increases, there is a problem that communication disconnection occurs due to packet delay or packet loss.

  In addition, the traffic distribution device described in Patent Document 2 described above has a problem in that it becomes a subsequent measure because another relay device is used when the traffic volume exceeds a predetermined value.

  Accordingly, an object of the present invention is to provide an IP telephone system capable of preventing an increase in RTP packets that are biased toward a specific communication path and preventing packet loss and delay as much as possible by ensuring equal RTP packet paths. It is to provide.

  In the IP telephone system of the present invention, in an IP telephone system in which a server that controls a call and a plurality of RTP terminators that control RTP packets are interposed, the server selects RTP terminators equally. The RTP packet path can be specified by managing RTP port numbers that are arranged in different communication areas and are notified to the originating IP device and the terminating IP device.

  The server includes an RTP termination device management table in which a unique number is registered in the network allocated for each RTP termination device managed by the server. Each entry in the RTP termination device management table includes Has a flag indicating whether or not the RTP terminator is in use, and has a LASTno area where the number of the last selected RTP terminator is registered, and receives a call setup request from the originating IP device The server searches the flags sequentially from the RTP terminator number registered next to LASTno, and selects an unused RTP terminator nearest to LASTno.

  In addition, each RTP terminator has a plurality of originating RTP port numbers registered in the RTP terminating device, and each entry has a flag indicating whether the port is in use or not. A plurality of destination RTP port numbers of the RTP terminator are registered, and each entry has a destination RTP port number management table having a flag indicating whether or not the port is in use. The search of the port number management table and the destination RTP port number management table is performed by call number, and when an RTP port number whose flag is IDLE is found, the number is determined as the source RTP port number and the destination RTP port number.

  Further, an emergency call RTP terminator is arranged on the network for the highest priority call (emergency call), an emergency call RTP terminator registration area is provided in the RTP terminator management table, and the calling IP device is urgent. When a special number is dialed at the time of call origination, the server may recognize that it is an emergency call from the special number, and may select an RTP terminator for emergency call from the RTP terminator management table.

  The present invention has a first effect that it is possible to specify a transmission / reception route of an RTP packet. The reason is that the server selects the RTP terminator, and the RTP terminator configures the RTP packet path.

  In addition, a configuration in which a specific RTP terminating device is arranged for an emergency call and the bandwidth can be guaranteed can achieve a second effect that communication for an emergency call can be guaranteed. it can.

[Description of configuration]
Next, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing an example of an IP telephone system according to the present invention. This IP telephone system includes an outgoing IP device 2, an incoming IP device 3, three RTP terminators 4, 5, 6, a server 1 that manages the RTP terminators 4, 5, 6, and five It consists of routers 7-11. Each of the RTP terminators 4, 5 and 6 manages the termination of the RTP packet and the RTP port number, and is arranged in different areas. In order to avoid complication of the drawing, only one outgoing IP device 2 and one incoming IP device 3 are shown, but actually, a plurality of outgoing IP devices 2 and incoming IP devices are included in the routers 7 to 11. 3 can be connected.

  The outgoing IP device 2 is connected to the router 7, the server 1 is connected to the router 8, the RTP terminator 4 is connected to the router 9, the incoming IP device 3 and the RTP terminator 5 are connected to the router 10, and the RTP terminator 6 is connected to the router 11. Further, the router 7 and the router 8 are connected, and the routers 8 to 11 are connected in a loop.

  Between the outgoing IP device 2 and the incoming IP device 3, a route A that passes through the router 8 to the router 10, a route B that goes straight from the router 8 to the router 10, and a route that goes from the router 8 to the router 10 via the router 11. Connection is possible with three routes of C.

  The server 1 has an RTP terminal device management table as shown in FIG. 2, and selects an RTP terminal device by this. In this table, a unique number is registered in the network allocated for each RTP terminal device managed by the server 1. Each entry has a flag indicating whether or not the RTP terminator is in use. In addition, the last selected (captured) number of the RTP terminating device is registered in the LASTno area.

  The server 1 that has received the call setting request from the originating IP device 2 sequentially searches for a flag from the RTP terminating device number registered after LASTno. Then, an unused RTP terminator nearest to LASTno is selected, and communication with the selected RTP terminator is determined.

Each of the RTP terminators 4 to 6 is arranged in a different communication area. Therefore, the concentration of RTP packets to be communicated can be prevented by selecting the RTP terminator. Each of the RTP terminators 4 to 6 includes a calling-side RTP port number management table shown in FIG. 3 and a called-side RTP port number management table shown in FIG. The former registers the number of the originating RTP port of the RTP terminator, and the latter registers the number of the destination RTP port of the RTP terminator, and each entry indicates whether the port is in use. Has a flag.
[Description of operation]
FIG. 6 is a sequence chart showing the operation of the IP telephone system of the present invention. First, in order to bring the RTP terminator under server control, each RTP terminator is registered in the RTP terminator management table.

  When a call setup request is sent from the originating IP device 2 to the server 1 (A in FIG. 6) and received, the server 1 receives the RTP terminator of the IDEL registered next to the LASTno area of the RTP terminator management table ( For example, the number of the RTP terminator 9) is selected (B in FIG. 6), and it is determined to communicate with the selected RTP terminator 9. Such a selection avoids biased use of the RTP terminator. Next, the server 1 issues a calling side RTP port number acquisition instruction to the selected RTP terminating device 9 (C in FIG. 6).

  The RTP terminating device 9 that has received the calling side RTP port number capture instruction searches the calling side RTP port number management table managed in its own device by the call number, and when the RTP port number whose flag is IDLE is found, that number Is determined as the originating RTP port number (D in FIG. 6). The flag is BUSY. The determined originating RTP port number is notified to the server 1 by an originating RTP port number capture response (E in FIG. 6).

  The server 1 grasps the originating RTP port number captured by the RTP terminating device 9 by the originating RTP port number capturing response. Thereafter, the server 1 notifies the calling IP device 3 of the calling RTP port number by a call setting request (F in FIG. 6).

  Then, the incoming IP device 3 calls the server 1 (G in FIG. 6), and in response to this, the server 1 calls the outgoing IP device 2 (H in FIG. 6). As a result, the ring tone can be heard at the outgoing IP device 2. The incoming IP device 3 responds to the RTP terminator 9 (I in FIG. 6), and the server 1 that has received this gives an instruction to acquire the incoming RTP port number to the RTP terminator 9 (in FIG. 6). J).

  The RTP terminating device 9 that has received the destination side RTP port number capture instruction searches the destination side RTP port number management table managed in its own device by the call number, and when it finds the RTP port number whose flag is IDLE, Is determined as the destination RTP port number (K in FIG. 6). The flag is BUSY. The determined originating RTP port number is notified to the server 1 by the incoming RTP port number capture response (L in FIG. 6).

  The server 1 grasps the incoming RTP port number captured by the RTP terminal device 9 by the incoming RTP port number acquisition response. Thereafter, the server 1 notifies the originating IP device 2 of the called RTP port number in response (M in FIG. 6).

  As a result, the originating IP device 2 knows the called RTP port number and the terminating IP device 3 knows the originating RTP port number, and can make a call between them (N in FIG. 6).

  When the calling IP device 2 and the receiving IP device 3 end the call, if the calling IP device 2 disconnects the line (O in FIG. 6), the calling side means that the server 1 ends the call to the RTP terminator 9 An instruction to release the destination RTP port number is issued (P in FIG. 6) to prompt the opening of the source RTP port number and the destination RTP port number.

  The RTP terminating device 9 that has received the calling / receiving side RTP port number release instruction releases the RTP port number used in the call. That is, the RTP port number flag used for the call in the originating RTP port number management table and the called RTP port number management table is returned to IDLE.

  Thereafter, the server 1 instructs the incoming IP device 3 to disconnect (R in FIG. 6). When the incoming IP device 3 responds to the server 1 with a disconnection response (S in FIG. 6), the server 1 sends it to the outgoing IP device 2. Tell (T in FIG. 6).

  As described above, the server 1 searches the RTP terminator management table for each order in which calls are made and selects the RTP terminator, so that it is possible to distribute the routes on which RTP packets are transmitted and received. . Referring to FIG. 1, for the first call, the RTP terminal device 9 is selected and RTP packets are transmitted and received using the path A. In the second call, the RTP terminal device 10 is selected and the RTP packet using the path B is transmitted / received. Thereafter, in the same manner, routes corresponding to the number of RTP terminating devices arranged under the server 1 are selected.

Also, since the RTP port numbers on the originating side and the terminating side are managed by the RTP terminator, and the RTP packet of the originating IP device 2 and the terminating IP device 3 can be transmitted / received using the RTP port number, the RTP terminator Makes it possible to use the RTP port of IDEL without controlling the RTP packet, that is, leaving the determination of the RTP port number to the originating IP device 2 and the terminating IP device 3.
[Other embodiments of the invention]
In this embodiment, the configuration is as shown in FIG. 1, but the RTP packet bandwidth control in the network is further devised. That is, an emergency call RTP terminator is arranged on the network for the highest priority call (emergency call) and is registered in the RTP terminator management table managed by the server 1 as shown in FIG. Establish an area.

  The originating IP device 2 dials a special number when making an emergency call. The server 1 recognizes that the call is an emergency call from the special number, and selects an RTP terminator for emergency call from the RTP terminator management table. With such a configuration, it is possible to guarantee the communication of an emergency call even during high traffic in the network.

Block diagram showing an example of the IP telephone system of the present invention The figure which shows an example of the RTP termination device management table with which a server is equipped The figure which shows the originating RTP port number management table with which an RTP termination device is provided. The figure which shows the incoming side RTP port number management table with which an RTP termination device is provided. The figure which shows the other example of the RTP termination device management table with which a server is equipped. Overview of operation

Explanation of symbols

1 server 2 outgoing IP device 3 incoming IP device 4-6 RTP terminator 7-11 router

Claims (4)

In an IP telephone system in which a server that controls calls and a plurality of RTP terminators that control RTP packets are interposed,
The server selects the RTP terminator equally,
2. The IP telephone system according to claim 1, wherein the RTP terminator is arranged in a different communication area and manages a RTP port number to be notified to a transmitting IP device and a receiving IP device, thereby enabling a RTP packet route to be specified. The server includes an RTP terminator management table in which a unique number is registered in a network allocated for each RTP terminator managed by the server,
Each entry in the RTP terminator management table has a flag indicating whether or not the RTP terminator is in use, and the LASTno area where the number of the last selected RTP terminator is registered. Have
The server that has received the call setup request from the originating IP device sequentially searches for a flag from the RTP terminator number registered next to LASTno, and selects an unused RTP terminator nearest to LASTno. The IP telephone system according to claim 1. Each of the RTP terminators has a plurality of originating RTP port numbers registered in the RTP terminating device, and each entry has an originating RTP port number management table having a flag indicating whether the port is in use or not. ,
A plurality of destination RTP port numbers of the RTP terminator are registered, and each entry has a destination RTP port number management table having a flag indicating whether the port is in use,
The calling RTP port number management table and the called RTP port number management table are searched by call number, and when the RTP port number whose flag is IDLE is found, the numbers are called the RTP port number and the called RTP port. 3. The IP telephone system according to claim 1, wherein the IP telephone system is determined by number. An emergency call RTP terminator is arranged on the network for the highest priority call (emergency call), and an emergency call RTP terminator registration area is provided in the RTP terminator management table,
When the calling IP device dials a special number at the time of emergency call transmission, the server recognizes that the call is an emergency call from the special number, and selects an RTP terminal device for emergency call from the RTP terminal device management table. Item 4. The IP telephone system according to items 1 to 3.

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