JP4247551B2 - VoIP trunk equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a VoIP trunk apparatus having a function for realizing, for example, a voice over IP (hereinafter simply referred to as VoIP) for transmitting and receiving voice signals on an IP network.
[0002]
[Prior art]
FIG. 6 is a block diagram showing a schematic configuration inside a telephone exchange system employing a conventional VoIP.
[0003]
A telephone exchange system 100 shown in FIG. 6 includes a router 102 connected to an IP network 101, a telephone exchange (hereinafter simply referred to as PBX) 110 that accommodates and connects an extension telephone 103, and a VoIP that establishes communication connection between the router 102 and the PBX 110. And a gateway 120.
[0004]
The PBX 110 communicates between an extension circuit (hereinafter simply referred to as LIN) 111 that accommodates and connects the extension telephone 103, a dedicated line trunk (hereinafter simply referred to as ODT) 130 that accommodates and connects the VoIP gateway 120, and the LIN 111 and the ODT 130. A time-division switch (hereinafter simply referred to as TSW) 112 for forming a path, a memory unit (hereinafter simply referred to as MM) 113 for storing various programs and the like, and a central control processing unit (hereinafter referred to as the PBX 110). , Simply referred to as a CPU) 114. The VoIP gateway 120 is externally attached to the PBX 110.
[0005]
FIG. 7 is a block diagram showing a schematic configuration inside the ODT 130 and the VoIP gateway 120.
[0006]
In FIG. 7, the ODT 130 has a function of mutually converting the PBX digital call control signal and the ODT digital call control signal between the PBX 110 and the ODT 130, and a function of mutually converting the PBX digital voice signal and the ODT digital voice signal. Between the ODT side signal converter 131, the ODT side ROM 132 for storing various programs, the ODT side RAM 133 for program work, the ODT digital call control signal between the ODT 130 and the VoIP gateway 120, the ODT analog call control signal Between the ODT side call control conversion unit 134 having the function of converting the analog call control signal for gate to the digital call control signal for ODT, and the ODT 130 and the VoIP gateway 120, the ODT digital voice signal For analog Function for converting the audio signal, and a ODT side speech converting unit 135 having a function of converting the gating analog audio signal to the ODT for digital audio signals, and a ODT side MPU136 for controlling the entire ODT130. The ODT side audio conversion unit 135 is synchronized based on, for example, a clock signal from the PBX 110.
[0007]
The VoIP gateway 120 includes a LAN interface 121 connected to the router 102, a DSP 122 that compresses / decompresses a voice signal, a gate ROM 123 for storing programs, a gateway RAM 124 for program operations, an IP network 101, and a VoIP gateway 120. A gate-side signal converter 125 having a function of interconverting into a gate digital call control signal and an IP digital call control signal, and a function of interconverting into a gate digital voice signal and an IP digital voice signal; A gate-side call having a function for converting an ODT analog call control signal into a gate digital call control signal and a function for converting a gate digital call control signal into a gate analog call control signal between the ODT 130 and the VoIP gateway 120 Control conversion 126 and the ODT 130 and the VoIP gateway 120, a gate side audio conversion having a function of converting an ODT analog audio signal into a gate digital audio signal and a function of converting a gate digital audio signal into a gate analog audio signal. Unit 127 and an ODT side MPU 128 that controls the entire VoIP gateway 120.
[0008]
Next, the operation of the conventional telephone exchange system 100 will be described.
[0009]
First, the operation at the time of transmission to the IP network 101 in the VoIP gateway 120 will be described.
[0010]
When receiving the ODT analog call control signal from the ODT 130, the gate side call control conversion unit 126 of the VoIP gateway 120 converts the ODT analog call control signal into a gate digital call control signal. Further, the gate-side signal converter 125 converts the gate digital call control signal into an IP digital call control signal.
[0011]
The LAN interface 121 packetizes this IP digital call control signal and transmits the packetized call control signal to the opposite device of the IP network 101 through the router 102. Therefore, the opposite device performs call setting based on this call control signal.
[0012]
Further, when the ODT analog audio signal is received from the ODT 130, the gate side audio converting unit 127 of the VoIP gateway 120 converts the ODT analog audio signal into a gate digital audio signal by PCM encoding. Further, the gate-side signal converter 125 converts the gate digital audio signal into an IP digital audio signal.
[0013]
The DSP 122 compresses the digital audio signal for IP. The LAN interface 121 packetizes the IP digital audio signal compressed by the DSP 122, and transmits the packetized audio signal to the opposite device of the IP network 101 through the router 102.
[0014]
Next, the operation at the time of reception from the IP network 101 in the VoIP gateway 120 will be described.
[0015]
When receiving the packetized call control signal from the router, the LAN interface 121 of the VoIP gateway 120 breaks down the call control signal and outputs an IP digital call control signal. The gate-side signal converter 125 converts the IP digital call control signal into a gate digital call control signal. The gate side call control conversion unit 126 converts the gate digital call control signal into a gate analog call control signal, and outputs the gate analog call control signal to the ODT 130. Therefore, the ODT 130 converts the gate analog call control signal into an ODT digital call control signal through the ODT side call control conversion unit 134, and thus considers the call control reception to the normal ODT 130, and the PBX 110 calls. Set up.
[0016]
Further, when receiving the packetized voice signal from the router, the LAN interface 121 of the VoIP gateway 120 breaks down the voice signal and outputs an IP digital voice signal. The DSP 122 expands this IP digital audio signal.
[0017]
The gate-side signal converter 125 converts the IP digital audio signal into a gate digital audio signal. The gate side audio conversion unit 127 converts the gate digital audio signal into a gate analog audio signal, and outputs the gate analog audio signal to the ODT 130. Therefore, the ODT 130 converts the gate analog audio signal into the ODT analog audio signal through the ODT side audio conversion unit 135, and thus the PBX 10 regards the audio reception as a normal ODT.
[0018]
As described above, according to the conventional telephone exchange system 100, the ODT 130 of the PBX 110 is connected to the IP network 101 via the VoIP gateway 120, thereby realizing VoIP that performs transmission and reception of voice signals between the PBX 110 and the IP network 101. Can be planned.
[0019]
In order to realize VoIP in this way, the VoIP gateway 120 is given a single IP address in advance from the IP network 101 side.
[0020]
For example, when the PBX 110 accommodates a plurality of extension telephones 103, the opposite device as the calling terminal on the IP network 101 side can make an incoming call to a specific VoIP gateway 120 based on this IP address, and the ODT 130 When the VoIP incoming call from the IP network 101 is detected, the CPU 114 of the PBX 110 selects an arbitrary extension telephone 103 from the plurality of extension telephones 103 and receives the selected extension telephone 103 to execute VoIP. Is.
[0021]
As described above, according to the conventional telephone exchange system 100, when the CPU 114 of the PBX 110 detects a VoIP incoming call from the IP network 101 to the VoIP gateway 120 through the ODT 130, an arbitrary extension telephone 103 is selected from the plurality of extension telephones 103. Thus, the VoIP call can be made to the selected extension telephone 103.
[0022]
[Problems to be solved by the invention]
However, according to the conventional telephone exchange system 100, since there is only one IP address assigned to the VoIP gateway 120, the opposite device as the transmitting terminal on the IP network 101 side can use the VoIP based on this IP address. The VoIP gateway 120 that accommodates the extension telephone 103 to be called can be specified. However, since the extension telephone 103 to be allocated after the VoIP gateway 120 depends on the control of the PBX 110, the IP network 101 side The opposite device cannot identify the extension telephone 103 that is the VoIP incoming call target.
[0023]
The present invention has been made in view of the above points, and an object of the present invention is to identify, from a plurality of extension telephones accommodated and connected to a telephone exchange, an extension telephone subject to VoIP reception from an originating terminal on the IP network side. An object of the present invention is to provide a VoIP trunk device that can be used.
[0024]
[Means for Solving the Problems]
In order to achieve the above object, a VoIP trunk device of the present invention has a switch interface connected to a telephone switch and an IP interface connected to an IP network, and a call control signal and voice between the switch interface and the IP interface. A VoIP trunk device that transmits and receives signals, and a plurality of IP addresses assigned to the IP interface When Storage means for associating and storing line numbers related to a plurality of lines connected to the exchange interface and the use status of the lines, and receiving an IP address from the IP network through the IP interface; A search unit that searches the storage unit for the corresponding line number; and a use status of the line of the line number searched by the search unit through the exchange interface, and when it is determined that the line is free When an incoming operation to the line is executed and it is determined that the line is in use, it corresponds to the IP address Of the line numbers stored in the storage means, different from the line in use The line number was searched and searched Another The usage status of the line, Another When it is determined that Another Control means for executing an incoming operation on the other line, and a line number capable of executing the incoming operation by the control means. Responded And a second control means for notifying the IP network that the incoming operation cannot be executed when it is determined that there are no lines.
[0025]
Therefore, according to the VoIP trunk device of the present invention, the plurality of IP addresses assigned to the IP interface and the telephone numbers related to the plurality of telephone lines connected to the exchange interface are stored in the storage means in association with each other. When an IP address from the IP network is received through the IP interface, a telephone number corresponding to the IP address is retrieved from the storage means, and an incoming operation to the telephone line related to the retrieved telephone number is executed. As a result, by assigning an IP address to each telephone line (extension telephone), a telephone line (extension telephone) targeted for VoIP reception from among a plurality of telephone lines (extension telephones) connected to the exchange interface is connected to the IP network. It can be specified from the side (IP network side transmitting terminal).
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a telephone exchange system showing an embodiment relating to a VoIP trunk device of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration inside the telephone exchange system according to the present embodiment.
[0027]
A telephone exchange system 1 shown in FIG. 1 includes a router 3 connected to an IP network 2 and a PBX 10 that accommodates and connects the router 3 and a plurality of extension telephones 4.
[0028]
The PBX 10 includes a LIN 11 that accommodates and connects a plurality of extension telephones 4, a VoIP trunk device (hereinafter simply referred to as VoIPT) 20 that accommodates and connects a router 3, a TSW 12 that forms a communication path between the LIN 11 and the VoIP T 20, and various types It has an MM 13 for storing programs and the like, and a CPU 14 for controlling the entire PBX 10.
[0029]
FIG. 2 is a block diagram showing a schematic configuration inside the VoIP 20.
[0030]
The VoIPT 20 shown in FIG. 2 includes a LAN interface 21 connected to the router 3, a VoIPT interface 22 that controls the interface between the PBX 10 and the LAN interface 21, an input / output unit 23 that inputs and outputs various information, and a ROM 24 for storing programs. And a RAM 25 for program work, an MPU 26 for controlling the entire VoIPT 20, and a control bus 27 for transmitting control data among the VoIPT interface 22, the input / output unit 23, the ROM 24, the RAM 25 and the MPU 26.
[0031]
FIG. 3 is a block diagram showing a schematic configuration inside the VoIPT interface 22.
[0032]
The VoIPT interface 22 includes an ODT side interface 30 connected to the TSW 12 and a gate side interface 40 connected to the router 3.
[0033]
The ODT side interface 30 includes an ODT side conversion unit 31 that mutually converts a call control signal and a voice signal between the PBX 10 and the gate side interface 40, an ODT side ROM 32 that stores various programs, and an ODT side RAM 33 for program work. And an ODT side MPU 34 for controlling the entire ODT side interface 30.
[0034]
When receiving the PBX digital call control signal, the ODT side conversion unit 31 converts the PBX digital call control signal into an ODT digital call control signal and transmits the ODT digital call control signal to the gate side interface 40. When receiving a PBX digital audio signal, the PBX digital audio signal is converted into an ODT digital audio signal, the ODT digital audio signal is transmitted to the gate side interface 40, and a gate digital call control. A function for converting the gate digital call control signal into a PBX digital call control signal when receiving a signal, and a function for converting the gate digital voice signal into a PBX digital voice signal when receiving a gate digital voice signal And have.
[0035]
The gate side interface 40 stores a gate side conversion unit 41 that mutually converts a call control signal and a voice signal between the ODT side interface 30 and the LAN interface 21, a DSP 42 that compresses or expands the voice signal, and various programs. It has a gate ROM 43, a gate RAM 44 for program operation, and a gate MPU 45 for controlling the entire gate interface 40.
[0036]
When receiving the ODT digital call control signal, the gate side conversion unit 41 converts the ODT digital call control signal into an IP digital call control signal. When receiving the ODT digital voice signal, the gate side conversion unit 41 receives the ODT digital call control signal. A function for converting an audio signal into an IP digital audio signal; a function for converting an IP digital call control signal into a gate digital call control signal when an IP digital call control signal is received; and an IP digital audio signal When received, the digital audio signal for IP is converted into a digital audio signal for gate.
[0037]
The DSP 42 expands the IP digital voice signal packet-decomposed by the LAN interface 21 to transmit the expanded IP digital voice signal to the gate side conversion unit 41 and the IP converted by the gate side conversion unit 41. By compressing the digital audio signal for use, the compressed IP digital audio signal is transmitted to the LAN interface 21.
[0038]
The gate side conversion unit 41 is assumed to synchronize between the gate side interface 40 and the ODT side interface 30 based on the clock signal of the ODT side conversion unit 31.
[0039]
Further, it is assumed that the VoIP 20 is assigned a plurality of IP addresses.
[0040]
FIG. 4 is an explanatory diagram showing the memory contents of the RAM 25 of the VoIP 20.
[0041]
In FIG. 4, the RAM 25 stores the plurality of IP addresses 25A, line numbers (telephone numbers) 25B related to the plurality of telephone lines connected to the ODT side interface 30, and usage status 25C of the line numbers in association with each other. For example, if the IP address is “100”, the MPU 26 searches for the line number “0” of the telephone line corresponding to the IP address, and the usage status of this line number “0” is busy. It can be recognized.
[0042]
The storage means described in the claims corresponds to the RAM 25, the search means and control means to the MPU 26, the exchange interface to the ODT side interface 30, and the IP interface to the gate side interface.
[0043]
Next, the operation of the telephone exchange system 1 showing this embodiment will be described.
[0044]
First, an operation at the time of transmission to the IP network 2 in the VoIP 20 will be described.
[0045]
When receiving the PBX digital call control signal from the PBX 10 side, the ODT side conversion unit 31 of the ODT side interface 30 of the VoIP 20 converts the PBX digital call control signal into an ODT digital call control signal, and this ODT digital call control signal. A call control signal is transmitted to the gate side interface 40.
[0046]
When receiving the ODT digital call control signal, the gate side conversion unit 41 of the gate side interface 40 converts the ODT digital call control signal into an IP digital call control signal, and converts the IP digital call control signal into the LAN interface. 21 is transmitted.
[0047]
The LAN interface 21 packetizes the IP digital call control signal and transmits the packetized call control signal to the opposite device of the IP network 2 through the router 3. Therefore, the opposite device performs call setting based on this call control signal.
[0048]
When receiving the PBX digital audio signal from the PBX 10 side, the ODT side conversion unit 31 converts the PBX digital audio signal into an ODT digital audio signal and transmits the ODT digital audio signal to the gate side interface 40. .
[0049]
When receiving the ODT digital audio signal, the gate side conversion unit 41 of the gate side interface 40 converts the ODT digital audio signal into an IP digital audio signal, and transmits the IP digital audio signal to the DSP 42. The DSP 42 compresses the digital audio signal for IP. The LAN interface 21 packetizes the IP digital voice signal compressed by the DSP 42 and transmits the packetized voice signal to the opposite device of the IP network 2 through the router 3.
[0050]
Next, the operation at the time of reception from the IP network 2 in the VoIPT 20 will be described.
[0051]
When receiving the packetized call control signal from the router 3, the LAN interface 21 of the VoIP 20 decomposes the call control signal into packets and outputs an IP digital call control signal.
[0052]
The gate side conversion unit 41 of the gate side interface 40 converts the IP digital call control signal into a gate digital call control signal and transmits the gate digital call control signal to the ODT side interface 30.
[0053]
The ODT side conversion unit 31 of the ODT side interface 30 converts the gate digital call control signal into a PBX digital call control signal and transmits the PBX digital call control signal to the PBX 10. Therefore, when receiving the PBX digital call control signal, the PBX 10 regards it as normal call control reception based on the PBX digital call control signal and performs call setting.
[0054]
Further, when receiving the packetized voice signal from the router 3, the LAN interface 21 decomposes the voice signal into packets and outputs an IP digital voice signal. The DSP 42 expands this IP digital audio signal.
[0055]
The gate side conversion unit 41 converts the expanded IP digital audio signal into a gate digital audio signal and transmits the gate digital audio signal to the ODT side interface 30.
[0056]
When receiving the gate digital audio signal, the ODT side conversion unit 31 of the ODT side interface 30 converts the gate digital audio signal into a PBX digital audio signal and transmits the PBX digital audio signal to the PBX 10. Therefore, when the PBX 10 receives the PBX digital audio signal, it is regarded as normal audio reception.
[0057]
Next, VoIP incoming call processing of the telephone exchange system 1 showing this embodiment will be described. FIG. 5 is a flowchart showing the processing operation of the MPU 26 related to the VoIP incoming processing of the VoIP T20.
[0058]
The VoIP incoming call processing shown in FIG. 5 refers to the extension telephone 4 (line number) targeted for VoIP reception from among the plurality of extension telephones 4 (line numbers) accommodated by the PBX 10 from the opposite device as the transmission terminal on the IP network 2 side. This is a process that can be specified.
[0059]
In FIG. 5, the MPU 26 determines whether an IP address has been received from the opposite device of the IP network 2 through the LAN interface 21 (step S11). If the MPU 26 has received an IP address, the MPU 26 searches for the line number corresponding to this IP address from the memory contents of the RAM 25 shown in FIG. 4 (step S12).
[0060]
Based on this search result, the MPU 26 determines whether or not the line number corresponding to the IP address is in the RAM 25 (step S13). When it is determined that there is a line number corresponding to this IP address, the MPU 26 searches the RAM 25 for the usage status corresponding to this line number, and determines whether or not the usage status corresponding to this line number is empty. (Step S14).
[0061]
When the MPU 26 determines that the usage status corresponding to the same line number is empty, the MPU 26 determines that this line number is the extension telephone 4 that is a VoIP incoming call, and performs an incoming call operation on this extension telephone 4 (step S15), this processing operation ends.
[0062]
If it is determined in step S14 that the usage status corresponding to the same line number is not empty, it is determined whether there is another line number other than this line number (step S16). If it is determined that there is another line number, the process proceeds to step S14 in order to recognize whether or not the usage status corresponding to this line number is empty. Note that the processing operation of step S16 considers the user's usability to connect to another extension telephone 4 as much as possible, although it is not the extension telephone 4 specified by the caller terminal on the IP network 2 side.
[0063]
If it is determined in step S16 that there is no other line number, an incoming call disable operation is executed to notify the opposite device side that the VoIP incoming operation corresponding to the same line number cannot be executed (step S17). ), This processing operation ends.
[0064]
If it is determined in step S11 that no IP address has been received, or if it is determined in step S13 that there is no line number corresponding to the IP address, this processing operation is terminated.
[0065]
According to the present embodiment, a plurality of IP addresses assigned to the gate side interface 40 of the VoIPT 20 and a line number related to a plurality of extension telephones 4 connected to the ODT side interface 30 are stored in the RAM 25 in association with each other. When an IP address from the IP network 2 is received through the gate side interface 40, a line number corresponding to the IP address is retrieved from the RAM 25, and a VoIP incoming operation to the extension telephone 4 related to the retrieved line number is performed. Since the IP address is assigned to each line number, the extension telephone 4 that is the target of VoIP reception from the plurality of extension telephones 4 connected to the ODT side interface 30 is sent from the originating terminal on the IP network 2 side. Can be identified.
[0066]
Further, according to the present embodiment, by incorporating the VoIPT 20 in which the ODT side interface 30 and the gate side interface 40 are packaged in the PBX 10 as compared with the case where the VoIP gateway is externally attached to the PBX as in the prior art. In addition, the installation space can be reduced, and the analog conversion of the voice signal and call control signal between the ODT and VoIP gateways between the ODT and the VoIP gateway as in the prior art is eliminated, thereby reducing the voice quality and generating the delay. Can be prevented.
[0067]
【The invention's effect】
According to the VoIP trunk apparatus of the present invention configured as described above, a plurality of IP addresses assigned to the IP interface and a telephone number related to a plurality of telephone lines connected to the exchange interface are associated with each other and stored. When the IP address from the IP network is received through the IP interface, the telephone number corresponding to the IP address is retrieved from the storage means, and the incoming operation to the telephone line related to the retrieved telephone number is executed. By assigning an IP address to each telephone line (extension telephone), the VoIP call target telephone line (extension telephone) is set to IP among a plurality of telephone lines (extension telephones) connected to the exchange interface. It can be specified from the network side (IP network side transmitting terminal).
[Brief description of the drawings]
FIG. 1 is a block diagram showing a schematic configuration inside a telephone exchange system showing an embodiment of a VoIP trunk device of the present invention.
FIG. 2 is a block diagram showing a schematic configuration inside a VoIP trunk device that is a main part related to the present embodiment;
FIG. 3 is a block diagram showing a schematic configuration inside an IPT interface showing a main part of the VoIP trunk device as the main part.
FIG. 4 is an explanatory diagram showing memory contents related to VoIP incoming call processing in the RAM of the VoIP trunk device as the main part;
FIG. 5 is a flowchart showing the processing operation of the MPU related to the VoIP incoming call processing of the VoIP trunk device as the main part.
FIG. 6 is a block diagram showing a schematic configuration inside a telephone exchange system using a conventional VoIP.
FIG. 7 is a block diagram showing a schematic configuration inside an ODT and a VoIP gateway which are main parts of a telephone exchange system using VoIP according to the prior art.
[Explanation of symbols]
2 IP network
10 Telephone exchange (PBX)
20 VoIP trunk equipment (VoIP)
25 RAM (storage means)
26 MPU (search means, control means)
30 ODT side interface (exchange interface)
40 Gate side interface (IP interface)

Claims (1)

A VoIP trunk apparatus having an exchange interface connected to a telephone exchange and an IP interface connected to an IP network, and transmitting and receiving a call control signal and a voice signal between the exchange interface and the IP interface,
A plurality of IP addresses assigned to the IP interface,
Storage means for storing line numbers associated with a plurality of lines connected to the exchange interface and the usage status of the lines in association with each other;
When receiving an IP address from the IP network through the IP interface, search means for searching the storage means for the line number corresponding to the IP address;
The use status of the line with the line number searched by the search means through the exchange interface is determined, and when it is determined that the line is empty, an incoming operation to the line is executed, and the line is in use. when it is judged that there is among the IP address corresponding with the line stored in said storage means number, usage another line above the busy line retrieved searching line another line number Control means for executing an incoming operation to the other line when it is determined that another line is empty,
Wherein the incoming operation is determined that there is no any line that corresponds to the line number that can be executed by the control unit, characterized in that it has a second control means for notifying that the incoming call operation can not be executed in the IP network VoIP trunk device.

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