JP4175250B2 - Exchange system and exchange device - Google Patents

Description

  The present invention relates to an exchange system and an exchange device, for example, an IP-PBX (PBX corresponding to the Internet protocol) capable of handling a plurality of VoIP (Voice over Internet Protocol) terminals as an extension terminal, and a system having the IP-PBX It can be applied to.

  FIG. 2 is a conceptual diagram showing an exchange system 1 centering on a conventional IP-PBX 2. The IP-PBX 2 has a VoIP line card 2A for accommodating the VoIP terminal 3 and a legacy terminal accommodating line card 2B for accommodating a conventional terminal (hereinafter referred to as a legacy terminal) 4 such as an analog telephone or an ISDN telephone. The various line cards 2A and 2B can be connected via a time-division bus (TD bus; audio bus) 2C (in FIG. 2, the internal configuration of the PBX 2 related to control is omitted). )

The VoIP line card 2A accommodates a plurality (maximum M) of VoIP terminals 3 via a LAN (or a dedicated line or the Internet) 5, for example. In a general PBX (legacy PBX), the extension terminal is a fixed connection by wire, and the voice path always passes through the PBX. Therefore, as many line cards as the number of accommodation terminals are accommodated in the exchange. In the IP-PBX 2 as well, the VoIP terminal 3 is treated as an extension terminal, and the control channel information and the voice path route of the channel are bundled between the line card 2A and the VoIP terminal 3. Note that a VoIP-compatible line card is described in Patent Document 1, for example.
Japanese translation of PCT publication No. 2003-508972

  However, unlike the legacy terminal 4, the VoIP terminal 3 does not pass through the VoIP line card 2A because communication between the VoIP terminals 3 can be exchanged on the LAN 5. Here, compared with the call between the VoIP terminal 3 and the legacy terminal 4, when there are more calls between the VoIP terminals 3, there were the following problems.

  The VoIP line card 2A needs only (n; n ≧ X / M) that can accommodate all (X) VoIP terminals 3 at the same time. 2A is increasing. That is, it can be said that there are many redundant (waste) hardware circuits.

  In other words, this problem indicates that the unit price per port in the line interface increases as the number of VoIP terminals 3 increases regardless of the amount of calls with the legacy terminal 4. In particular, such a problem becomes conspicuous when an audio compression function as described later is installed.

  In addition, when communicating between the IP-PBX 2 and the VoIP terminal 3, there is a case where a voice compression function is added because there are cases where the dedicated line (5) with a limited bandwidth is used. The voice compression function makes the card complicated or expensive, but since the VoIP terminal 3 is fixedly fixed in which VoIP line card 2A is accommodated during communication, the voice compression function is provided for all VoIP line cards 2A. (2Aa) must be installed. Note that the audio compression function 2Aa needs to be able to support a plurality of types of compression schemes depending on the type of the VoIP terminal 3 and the like.

  For this reason, there is a demand for an exchange device that can be configured simply and inexpensively, and an exchange system that includes the exchange device even if it can cope with a terminal that is not directly connected to the line interface.

In order to solve this problem, the first aspect of the present invention accommodates X first type terminals that can directly communicate with each other via a predetermined network via the network and a plurality of conventional types. A switching apparatus that accommodates a second type terminal and enables mutual communication between any one of the first type terminals and any one of the second type terminals. The control information is processed, and call control information is exchanged between the call control means for forming call control information for the first type terminal and the first type terminal via the network , Y ( Y <X) The communication information main body is exchanged via the network between the first type terminal control information accommodating means for performing the processing for the first type terminal for the channel and the first type terminal. Above M (M ≦ Y) channels The processing associated with the serial first type of terminal, said first type terminal control information receiving means and another body, possess a first type terminal communication information receiving means, said call control means, any of the first For each call related to one type of terminal, the path route of the communication information body between the first type terminal and the first type terminal communication information accommodating unit is transferred from the first type terminal control information accommodating unit to the first type. The terminal is notified .

Further, the second aspect of the present invention accommodates X first type terminals that can directly communicate with each other via a predetermined network via the network, and a plurality of conventional second type terminals. And an exchange device that enables mutual communication between any of the first type terminals and any of the second type terminals, the first type terminal, and the second type terminal. (1) the switching device processes call control information from the first type terminal and forms call control information to the first type terminal; First type terminal control information accommodating means for performing processing on the first type terminal for Y (Y <X) channels, which exchanges call control information with the first type terminal via the network. Communication information with the first type terminal. The body exchanges through the network, M (M ≦ Y) performs the processing for the first type of terminal channels, and the first type terminal control information receiving means separate, first type terminal (2) The call control means includes a communication information storage means for each call related to any of the first type terminals, between the first type terminal and the first type terminal communication information storage means. The path route of the communication information body is notified from the first type terminal control information accommodating means to the first type terminal. (3) The first type terminal transmits call control information to the first type terminal control information. The communication information body is exchanged with the first type terminal communication information accommodation means.

  According to the present invention, a plurality of first type terminals that can directly communicate with each other via a predetermined network are accommodated via the network, and a plurality of conventional second type terminals are accommodated, An exchange device that enables mutual communication between any of the first type terminals and any of the second type terminals separates the call control information and the communication information main body from the first type terminals and separates them. Since the exchange is made with this path, the configuration of the exchange apparatus can be simplified and made inexpensive.

  Hereinafter, an embodiment of an exchange system and an exchange apparatus according to the present invention will be described in detail with reference to the drawings. Here, FIG. 1 is a block diagram showing the overall configuration of the exchange system of this embodiment.

  The switching system 10 of this embodiment includes an IP-PBX 11, a VoIP terminal 12, and a legacy terminal 13. The IP-PBX 11 can accommodate a plurality of VoIP terminals 12 as extension terminals via a LAN (or a dedicated line or the Internet) 14. The IP-PBX 11 includes a VoIP terminal control card 20, a VoIP voice trunk 21, a compression function circuit 22, a call control unit 23, and a legacy terminal accommodating line card 24. A time division bus (TD bus) 25 as a voice bus is a VoIP. The control bus 26 is connected to the voice trunk 21 and the legacy terminal accommodating line card 24, and the control bus 26 is connected to the VoIP terminal control card 20, the VoIP voice trunk 21, the call control unit 23, and the legacy terminal accommodating line card 24. The compression function circuit 22 is directly connected to the VoIP voice trunk 21.

  In FIG. 1, the VoIP terminal control card 20 and the VoIP voice trunk 21 appear to have a port for each VoIP terminal 12 in order to indicate that it can support a plurality of VoIP terminals 12. And the VoIP voice trunk 21 has only one (or a plurality) of connection ports with the LAN 14.

  In this embodiment, the control signal transmission / reception configuration of each VoIP terminal 12 is connected to the VoIP terminal control card 20 via the LAN 14, and the voice signal transmission / reception configuration of each VoIP terminal 12 is configured to be VoIP via the LAN 14. Connected to the voice trunk 21.

  3A shows a functional configuration inside the conventional VoIP line card 2A, FIG. 3B shows a functional configuration inside the VoIP terminal control card 20, and FIG. A functional configuration of the VoIP voice trunk 21 is shown.

  The VoIP terminal control card 20 performs control related to the VoIP terminals 12 for Y channels equal to or less than the number of VoIP terminals X. On the other hand, the VoIP voice trunk 21 performs only an interwork process (transfer process for absorbing a difference between voice signal protocols) of voice paths for M channels (M ≦ Y).

  The conventional VoIP line card 2A has a LAN interface unit 30 that interfaces with the LAN 5 as a common element of the control system and the voice processing system, and controls the interface with the control bus (not shown in FIG. 2) as the control system. A bus interface unit 31 and a control CPU unit 32 that performs control packet processing, in-line card control, and terminal control are included. As a voice processing system, a TD bus interface unit 33 that interfaces with the TD bus 2C, and a compression process. An audio processing unit 34 that performs protocol conversion or the like along a communication direction for an irrelevant audio signal, a compression circuit interface unit 35 that applies an audio signal related to compression processing to the audio compression function unit 2Aa, and executes compression or decompression. , A selector for selecting between the audio processing unit 34 and the compression circuit interface unit 35. And a section 36 and 37.

  As shown in FIG. 3B, the VoIP terminal control card 20 divides the LAN interface unit 30-1, the control bus interface unit 31 and the control CPU unit 32 among the components shown in FIG. As shown in FIG. 3C, the VoIP voice trunk 21 includes a LAN interface unit 30-2, a TD bus interface unit 33, a voice processing unit 34, a compression unit among the components shown in FIG. A circuit interface unit 35 and selector units 36 and 37 are provided for M channels.

  The control bus 26 is also connected to the TD bus interface unit 33. Further, the compression circuit interface unit 35 may have m channels smaller than the M channels (since the compression function circuit 22 supports m channels as will be described later).

  The compression function circuit 22 compresses the voice signal to the VoIP terminal 12 given from the VoIP voice trunk 21 (its compression circuit interface unit 35) when the VoIP terminal 12 used for communication complies with the compression coding method. The compressed voice signal from the VoIP terminal 12 given from the VoIP voice trunk 21 (the compression circuit interface unit 35) is decompressed and sent back to the VoIP voice trunk 21. Here, since there is a possibility that the applied compression encoding method is different depending on each VoIP terminal 12, the compression function circuit 22 is adapted to support a plurality of types of compression encoding methods.

  The call control unit 23 performs call control of all the line cards 20 and 24 and the trunk 25 accommodated in the IP-PBX 11, and transmits a control bus 26 to the line cards 20, 24 and the trunk 25 for information necessary for call control. Is to be sent through.

  As described above, the VoIP voice trunk 21 processes the interwork portion of the voice path of the conventional VoIP line card 2A, but is higher than the conventional VoIP line card 2A (call control unit 23). A function to set a call path with the VoIP terminal 12 that communicates with the path setting instruction information from, and a function to return busy information to the host when resource busy (when all channels are used) The TD bus interface unit 33 has these additional functions.

  The VoIP terminal 12 of this embodiment exchanges control information similar to the conventional one with the VoIP terminal control card 20, and in addition to this, the call control unit 23 via the VoIP terminal control card 20. Thus, information on which VoIP voice trunk 21 and voice path is established is obtained, and voice packets are transmitted / received to / from the designated VoIP voice trunk 21. The VoIP terminal 12 internally stores information about which VoIP voice trunk 21 and voice path is established obtained from the call control unit 23, and adds the information to the voice packet when transmitting the voice packet. To send to. Note that the VoIP terminal 12 has fixed information for establishing a control path with the VoIP terminal control card 20. Information for establishing a voice path is given for each call, but may be given for each predetermined period from the IP-PBX 11 side.

  The legacy terminal 13 and the legacy terminal accommodating line card 24 of this embodiment are the same as the conventional ones.

  Next, a call control operation for communication between a certain VoIP terminal (hereinafter, denoted by reference numeral 12P) and the legacy terminal 13 will be described. In the following description, it is assumed that a certain VoIP terminal 12P is a calling side.

  Call information from a certain VoIP terminal 12P to the legacy terminal 13 is input to a predetermined VoIP terminal control card 20 via the LAN 14, and the VoIP terminal control card 20 passes to the call control unit 23 via the control bus 26. Given.

  The call control unit 23 confirms that the legacy terminal 13 is not busy, before confirming whether the legacy terminal 13 is busy, or in parallel with it, for example, each built-in Based on the operation status information (for example, the number of channels that the VoIP voice trunk 21 is currently communicating with) the VoIP voice trunk 21, the VoIP voice trunk 21 that sets the voice path for the current call is determined. Then, the determined VoIP voice trunk 21 is given a path setting instruction including information on the time slot in the TD bus 25 to be used and information on the compression method (which may be uncompressed) via the control bus 26. . The information on the compression method related to the VoIP terminal 12P may be taken from the VoIP terminal 12P each time, and a table describing the correspondence between the VoIP terminal 12P and the compression method is provided in the call control unit 23. The information in the table may be referred to be included in the path setting instruction. When the legacy terminal 13 is busy, a message to that effect (busy) or the like is returned to the VoIP terminal 12P at an appropriate timing.

  Such a path setting instruction is given to the TD bus interface unit 33 in the VoIP voice trunk 21. FIG. 4 is a flowchart showing the processing of the TD bus interface unit 33, particularly its resource management function unit. Note that a dedicated resource management function unit independent of the TD bus interface unit 33 connected to the control bus 26 may be provided in the VoIP voice trunk 21 to execute the processing shown in FIG.

  When a resource management function unit such as the TD bus interface unit 33 receives a path setting instruction with the VoIP terminal 12P in a standby state (initial state) of control information from the control bus 26 (S100), based on the path setting instruction It is determined whether or not the VoIP terminal 12P adopts a compression encoding method (S101).

  If the compression coding method is not employed, it is determined whether or not a non-compression channel is available in the VoIP voice trunk 21 (S102). For example, if the VoIP voice trunk 21 can handle M channels, and the compression function circuit 22 connected to the VoIP voice trunk 21 can handle m channels, (M−m) pieces. These channels are uncompressed channels.

  If the uncompressed channel is not available, the resource management function unit of the VoIP voice trunk 21 notifies the call control unit 23 of channel busy information via the control bus 26 (S103). Return to state. At this time, the call control unit 23 may reissue a path setting instruction to the other VoIP voice trunk 21, and the predetermined VoIP terminal control card 20 makes the calling side VoIP terminal 12P busy. You may make it notify.

  If the VoIP terminal 12P adopts the compression coding method, it is determined whether or not a compression channel is available in the VoIP voice trunk 21 (S104). That is, it is determined whether or not the compression function circuit 22 is ready for a new channel.

  If the compression channel is not available, the process proceeds to the above-described determination process (S102) as to whether or not the non-compression channel is available. That is, when the compression channel is not available, the busy side is not immediately notified to the VoIP terminal 12P on the calling side, but it is confirmed whether or not communication without compression is possible.

  When the compression channel is free (positive result in step S104) or when the non-compression channel is free (positive result in step S102), the management in the resource management function unit of the VoIP voice trunk 21 is performed. In the table, the path information between the vacant channel (the presence or absence of compression; it will be used channel after registration) and the VoIP terminal 12P is registered, and then the channel is enabled and voice communication is started (S105, S106). ). The registration process to the management table includes a process of notifying the call control unit 23 that the registration has been made. At this time, the call control unit 23 sends the VoIP voice trunk 21 and the voice via the VoIP terminal control card 20. Information on whether to establish a path is given to the VoIP terminal 12P. Thereby, the VoIP voice trunk 21 and the VoIP terminal 12P perform voice packet transmission / reception control (S107). When the VoIP voice trunk 21 sends a voice packet to the VoIP terminal 12P, information that the voice packet reaches the VoIP terminal 12P is set in the management table described above even through the LAN 14. Based on the path information, it is added to the voice packet.

  The resource management function unit of the VoIP voice trunk 21 waits for an instruction to end communication from the host (call control unit 23) for such a used channel (S108). When instructed, the channel is invalidated, the corresponding channel in the management table is made free (S109), and the initial state is restored.

  When the number of channels m of the compression function circuit 22 is equal to the number of channels M of the VoIP voice trunk 21, the channel of the compression function circuit 22 is also confirmed by checking only the empty channels in the VoIP voice trunk 21. Will be.

  Further, the resource management processing of the VoIP voice trunk 21 when the legacy terminal 13 becomes the calling side to the VoIP terminal 12P is the same as described above, and the description thereof is omitted.

  According to the exchange system of the above embodiment, the following effects can be obtained.

  The IP-PBX 11 prepares VoIP voice trunks 21 corresponding to the number of call paths that are considered to occur at the same time between the legacy terminal 13 and the VoIP terminal 12 accommodated in the IP-PBX 11 instead of the number of VoIP terminals 12 that can be extensions. Then, a call between the legacy terminal 13 and the VoIP terminal 12 can be realized.

  In addition, by connecting the compression function circuit 22 having the number of channels (m) equal to or less than the number of channels (M) that can be supported by one VoIP voice trunk 21 to the VoIP voice trunk 21, VoIP corresponding to the compression coding scheme is provided. Voice communication between the terminal 12 and the legacy terminal 13 can be realized.

  Furthermore, since the call path and the control path are separated from the VoIP terminal, the hardware of the VoIP terminal control card 20 can be reduced in size, and the processing capacity of the control becomes redundant. You can control the number of channels.

  FIG. 5 is a conceptual illustration of such an effect. The conventional VoIP line card has a voice packet processing unit for the number of accommodated channels (n) and a control packet processing unit common to the n channels. In the case of the card 20, it is possible to perform channel control processing several times (for example, five times). Note that the time required for call control is a small part of the time for voice communication, and the card can be shared by a plurality of channels.

  By combining the above effects, it is possible to reduce the amount of hardware of the switching system and the IP-PBX, and it is also possible to expect the cost reduction and the power consumption reduction in the IP-PBX.

(B) Other Embodiments In the above embodiment, the switching apparatus is an IP-PBX. However, the technical idea of the present invention can also be applied to a station switching apparatus.

  In addition, although the terminal that can directly communicate with each other via a LAN (or a dedicated line, the Internet, or the like) without using an exchange device is shown as a VoIP terminal, other devices may be used. For example, a terminal capable of frame relay transfer may be used. In addition, the types of networks that these terminals and devices corresponding thereto communicate with each other are arbitrary, and the dedicated lines as described above are also included in the concept of networks.

  The voice communication in the above embodiment is a concept including communication using a voice band of a modem signal or a data signal, and the present invention is not limited to voice communication, and image communication, data communication, etc. It can also be applied to. For example, an exchange system that handles an ATM terminal in a bank in the same manner as the VoIP terminal of the embodiment may be used.

It is a block diagram which shows the whole structure of the exchange system of embodiment. It is a block diagram which shows the whole structure of the conventional exchange system. It is a block diagram which shows the internal structure of the VoIP terminal control card | curd and VoIP voice trunk of embodiment. It is a flowchart which shows the operation | movement at the time of the voice path setting instruction | indication of the VoIP voice trunk of embodiment. It is explanatory drawing of the effect of the exchange system of embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Switching system, 11 ... IP-PBX, 12 ... VoIP terminal, 13 ... Legacy terminal, 14 ... LAN (or leased line and the Internet), 20 ... VoIP terminal control card, 21 ... VoIP voice trunk, 22 ... Compression function circuit , 23 ... call control unit, 24 ... legacy terminal accommodating line card, 25 ... time division bus (TD bus), 26 ... control bus.

Claims (4)

X first type terminals that can directly communicate with each other via a predetermined network are accommodated via the network, and a plurality of conventional second type terminals are accommodated, In an exchange device that enables mutual communication between a first type terminal and any one of the second type terminals,
Call control means for processing call control information from the first type terminal and forming call control information for the first type terminal;
First type terminal control information accommodating means for performing processing on the first type terminal for Y (Y <X) channels, which exchanges call control information with the first type terminal via the network. When,
The first type terminal control information for performing processing on the first type terminal for M (M ≦ Y) channels that exchanges the communication information main body with the first type terminal via the network. the containment means possess separate and a first type terminal communication information receiving means,
For each call related to any of the first type terminals, the call control means determines the path route of the communication information main body between the first type terminal and the first type terminal communication information accommodating means, as the first type terminal. An exchange apparatus characterized by notifying the first type terminal from the control information accommodating means . The first type terminal communication information accommodation means is a function section for managing information of the first type terminal in communication, a function section for determining whether the path setting instruction from the call control means is busy, 2. The switching apparatus according to claim 1 , further comprising a function unit for transmitting said call control means heavy information when busy. In response to the path setting instruction from the call control means, the first type terminal communication information accommodating means determines whether or not it is busy in consideration of the number of channels that can be subjected to compression / decompression processing of communication information. The exchange device according to claim 2 , wherein X first type terminals that can directly communicate with each other via a predetermined network are accommodated via the network, and a plurality of conventional second type terminals are accommodated, In an exchange system having an exchange device that enables mutual communication between a first type terminal and any one of the second type terminals, the first type terminal, and the second type terminal,
The exchange device is
Call control means for processing call control information from the first type terminal and forming call control information for the first type terminal;
First type terminal control information accommodating means for performing processing on the first type terminal for Y (Y <X) channels, which exchanges call control information with the first type terminal via the network. When,
The first type terminal control information for performing processing on the first type terminal for M (M ≦ Y) channels , exchanging the communication information main body with the first type terminal via the network. A first type terminal communication information accommodation unit separate from the accommodation unit;
For each call related to any of the first type terminals, the call control means determines the path route of the communication information main body between the first type terminal and the first type terminal communication information accommodating means, as the first type terminal. From the control information storage means, notify the first type terminal,
The switching system according to claim 1, wherein the first type terminal exchanges call control information with the first type terminal control information accommodation unit, and exchanges a communication information body with the first type terminal communication information accommodation unit.

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