JP2004343437A - Radio telephony system, ip-adaptable radio base station equipment and ip-pbx - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve a radio telephony system using an IP-PBX (Internet Protocol-Private Branch Exchange), and IP-adaptable radio base station equipment and capable of controlling an increase in traffic in an IP network. <P>SOLUTION: In the IP-PBX 2, a main control section 24 outputs instructions indicative of the transmission start and transmission stop of a holding tone or a local tone with respect to PHS (Personal Handy Phone System) terminals 3 to the IP-adaptable PHS base station equipment 1 through a LAN (Local Area Network) 4. The IP-adaptable radio base station equipment 1 has: a tone generation section 131 outputting the holding tone and the local tone; and a selector 133 controlling the transmission of the holding tone or the local tone outputted by the tone generation section 131 to the PHS terminals 3 in accordance with the instructions received from the IP-PBX 2 through the LAN 4. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a wireless telephone system including an IP-PBX (Internet Protocol-Private Branch Exchange) and an IP-compatible wireless base station device.
[0002]
[Prior art]
BACKGROUND ART A wireless telephone system for business use is known as a system for enabling a wireless telephone such as a PHS (Personal Handy-phone System) terminal to be used as an extension telephone. FIG. 5 is a schematic diagram of a conventional business PHS system. As shown in the figure, the PBX includes a PBX 6 and a PHS base station device 7 that connects the PHS terminal 3 to the PBX 6 via a digital telephone line 8. In such a conventional PHS system for business use, a hold tone and a local tone are generated by the PBX and transmitted from the PBX to the PHS terminal using a communication path set between the PBX and the PHS terminal via the PHS base station device. It is generally transmitted (Patent Document 1). The local tone is a tone such as a dial tone or a busy tone transmitted to the telephone.
[0003]
[Patent Document 1]
JP-A-11-187131
[0004]
[Problems to be solved by the invention]
There has been proposed an IP-PBX that controls an IP telephone, a Voice over IP (VoIP) gateway device, and the like on an IP network to provide a PBX function. Also, an IP-compatible wireless base station device that connects a wireless telephone such as a PHS terminal to an IP network has been proposed. By connecting the IP-PBX and the IP-compatible wireless base station device to an IP network, for example, an existing LAN (Local Area Network) laid in a business office, an ISDN line or the like is used for connection between the PBX and the base station device. It is possible to construct a business-use wireless telephone system without newly laying a telephone line.
[0005]
However, when a business-use wireless telephone system is constructed using an IP-PBX and an IP-compatible wireless base station device, as in the technique described in Patent Document 1, a hold tone or a local tone is transmitted using an IP-PBX. The following problem arises when the packet is generated and transmitted to the wireless terminal via the IP-compatible wireless base station device. In other words, while the hold tone and the local tone are being transmitted, the IP packet storing the hold tone and the local tone continues to flow in the IP network, thereby increasing the traffic of the IP network. Therefore, the communication environment of another network terminal connected to the IP network may be deteriorated.
[0006]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a wireless telephone system using an IP-PBX and an IP-compatible wireless base station device capable of suppressing an increase in traffic of an IP network. Is to make it happen.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, a wireless telephone system according to the present invention includes an IP-PBX and an IP-compatible wireless base station device that connects a wireless telephone to the IP-PBX via an IP network.
[0008]
The IP-PBX includes an instruction unit that outputs an instruction to start and stop transmitting a hold tone or a local tone to the wireless telephone to the IP-compatible wireless base station device via the IP network. The IP-compatible radio base station apparatus further comprises: tone output means for outputting a hold tone and a local tone; and a hold tone output by the tone output means in accordance with the instruction received from the IP-PBX via the IP network. Or selection control means for controlling transmission of a local tone to the wireless telephone.
[0009]
According to the present invention, transmission start and transmission stop instructions of the hold tone or the local tone are transmitted from the IP-PBX to the IP-compatible wireless base station device via the IP network. Therefore, during the period when the hold tone or the local tone is being transmitted, the IP packet storing the hold tone or the local tone does not continue to flow in the IP network. For this reason, it is possible to suppress an increase in traffic on the IP network.
[0010]
Note that, in the IP-compatible wireless base station device, when a unit including a CPU is used for each of an IP communication processing unit that performs communication with the IP network and a wireless communication processing unit that performs communication with the wireless terminal, It is preferable to provide a FIFO for relaying control and / or transmission / reception of program data between the CPU of the IP communication processing means and the CPU of the wireless communication processing means.
[0011]
With this configuration, an interface between the CPU of the IP communication processing unit and the CPU of the wireless communication processing unit can be realized with a simple configuration.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described.
[0013]
FIG. 1 is a schematic diagram of an office PHS system to which an embodiment of the invention is applied. As shown in the figure, the office PHS system of the present embodiment includes an IP-compatible PHS base station device 1, an IP-PBX 2, and at least one PHS terminal 3. Here, the IP-compatible PHS base station device 1 and the IP-PBX 2 are connected by a LAN 4. The IP-PBX 2 is connected to a public network (not shown) via at least one ISDN line 5.
[0014]
In the above configuration, the IP-compatible PHS base station device 1 connects the PHS terminal 3 to the IP-PBX 2 via the IP network (LAN 4). Further, the IP-PBX 2 controls the PHS base station device 1 on the IP network (LAN 4) to provide a PBX function. Thereby, the PHS terminal 3 is connected to the public network or connected to another PHS terminal 3.
[0015]
Next, the IP-PBX 2 and the IP-compatible PHS base station device 1 will be described in detail. First, the IP-PBX 2 will be described.
[0016]
The IP-PBX 2 includes an ISDN line accommodating unit 21, a VoIP + LAN processing unit 22, a switch unit 23, and a main control unit 24, as shown in FIG.
[0017]
The ISDN line accommodation unit 21 accommodates at least one ISDN line 5. Then, for each ISDN line 5, an ISDN signal (ISDN basic interface (2B + D)) is transmitted to and received from the switch unit 23.
[0018]
The VoIP + LAN processing unit 22 performs connection processing with the LAN 4, and performs RTP (Real-time Transport Protocol) for voice processing and SIP (Session Initiation Protocol) or H.264 for call control processing. H.323 is processed, and a VoIP call is made with the IP-compatible PHS base station apparatus 1. Further, at least one ISDN signal is transmitted / received to / from the switch unit 23. Then, the VoIP + LAN processing unit 22 performs a conversion process between an ISDN signal transmitted / received to / from the switch unit 23 and an IP packet (VoIP packet) transmitted / received to / from the IP-compatible PHS base station apparatus 1.
[0019]
The switch unit 23 performs an exchange process between each ISDN signal transmitted / received to / from the VoIP + LAN processing unit 22 and each ISDN signal transmitted / received to / from the ISDN line accommodating unit 21.
[0020]
The main control unit 24 performs overall control of each unit of the IP-PBX 2 and performs various processes such as call control.
[0021]
The configuration and operation of the IP-PBX 2 described above are basically the same as those of the existing IP-PBX. However, the IP-PBX 2 of the present embodiment transmits the IP packet storing the hold tone or the local tone to the PHS terminal 3 via the IP-compatible PHS base station device 1 during the period of sending the hold tone or the local tone to the PHS terminal 3. 3 is not sent. Instead, the following processing is performed.
[0022]
That is, the main control unit 24 monitors the transmission start timing of the hold tone or the local tone to the PHS terminal 3 for each B channel, and when the timing is reached, the port number assigned to the B channel and the tone The VoIP + LAN processing unit 22 generates an IP packet storing a tone transmission start instruction including the type and sends the IP packet to the IP-compatible PHS base station apparatus 1. Further, the main control unit 24 monitors the transmission end timing of the hold tone or the local tone to the PHS terminal 3 for each B channel, and when the timing is reached, the port number and tone of the port number allocated to the B channel are monitored. The VoIP + LAN processing unit 22 generates an IP packet storing a tone transmission stop instruction including the type, and transmits the generated IP packet to the IP-compatible PHS base station apparatus 1.
[0023]
Next, the IP-compatible PHS base station device 1 will be described.
[0024]
The IP-compatible PHS base station device 1 includes a VoIP + LAN processing unit 11, a wireless communication + communication control unit 12, and a logic unit 13, as shown in FIG.
[0025]
The VoIP + LAN processing unit 11 performs a connection process with the LAN 4 and performs a VoIP call with the IP-PBX 2. Also, it sends and receives voice (call) data and control data (including programs) to and from the logic unit 13. Then, the VoIP + LAN processing unit 11 performs a conversion process between an IP packet (VoIP packet) transmitted / received to / from the IP-PBX 2 and voice data / control data transmitted / received to / from the logic unit 13. Further, in accordance with the tone transmission start instruction or the stop instruction received from the IP-PBX 2, the VoIP + LAN processing unit 11 outputs the hold tone and the local tone to the PHS terminal 3 through the B channel to which the port number included in the instruction is assigned. The logic unit 13 is controlled as described above.
[0026]
The wireless communication + communication control unit 12 performs wireless communication with the PHS terminal 3 by using, for example, RCR STD-28 which is a standard of the PHS system for business use. The wireless communication + communication control unit 12 performs a process of relaying voice (call) data between the PHS terminal 3 and the logic unit 12, and performs call control according to the call control data received from the PHS terminal 3 and the logic unit 12. Perform processing.
[0027]
The logic unit 13 includes a tone generation unit 131, an audio data processing unit 132, a selector 133, an encoding / decoding unit 134, and a control data buffer 135.
[0028]
The tone generating section 131 outputs a hold tone or a local tone according to an instruction from the VoIP + LAN processing section 11.
[0029]
The audio data processing unit 132 separates the audio data received from the VoIP + LAN processing unit 11 for each pair of B channels (two of the B channels), outputs the separated data to the selector 133, and outputs the data to the selector 133. The received audio data for each pair of B channels is multiplexed and output to the VoIP + LAN processing unit 11.
[0030]
The selector 133 selects one of the output of the tone generator 131 and the output of the audio data processor 132 for each B channel according to an instruction from the VoIP + LAN processing unit 11.
[0031]
The encoding / decoding unit 134 encodes the audio data or the tone data (data for each pair of B channels) received from the selector 133 and outputs the encoded data to the wireless communication + communication control unit 12 and the wireless communication + communication. The encoded data of the audio data received from the control unit 12 is decoded, and the decoded data (data for each pair of B channels) is output to the audio data processing unit 132.
[0032]
The control data buffer 135 is a relay buffer for control data (including call control data and programs) transmitted and received between the VoIP + LAN processing unit 11 and the wireless communication + communication control unit 12.
[0033]
FIG. 2 is a diagram illustrating an example of a hardware configuration of the IP-compatible PHS base station device 1.
[0034]
The VoIP + LAN processing unit 11 has a PHY chip 111 that provides a function of a physical interface of 10/100 BASE-T, and an EBI that provides a function of an internal interface between the tone generation unit 131, the audio data processing unit 132, and the control data buffer 135. An (External Bus Interface) chip 112, a CPU 113, and a memory 114 that stores programs and data executed by the CPU 113 and that functions as a work area of the CPU 113 are connected by an internal bus.
[0035]
The CPU 113 performs RTP for voice processing and SIP or H.264 for call control processing. 323, and performs VoIP communication with the VoIP + LAN processing unit 22 of the IP-PBX 2. Further, based on the destination address of the IP packet received via the PHY chip 111 and the port number of the UDP (or TCP) header, the destination of the data stored in the packet is determined by the audio data processing unit 132 and the control data. The EBI chip 112 is controlled to be one of the buffers 135 for use.
[0036]
The CPU 113 extracts a tone transmission start instruction and a tone transmission stop instruction from an IP packet received via the PHY chip 111 and having the address of the own device (the IP-compatible PHS base station device 1) as a destination address. The tone generator 131 and the selector 134 are controlled according to the extracted instruction.
[0037]
The audio data processing unit 132 includes a DSP (Digital Signal Processor) 1321, a first adjustment buffer 1322, and a second adjustment buffer 1323.
[0038]
The DSP 1321 separates the audio data received from the VoIP + LAN processing unit 11 for each pair of B channels, and outputs the separated data to the first adjustment buffer 1322. Also, the audio data for each pair of B channels received from the second adjustment buffer 1323 is multiplexed and output to the VoIP + LAN processing unit 11. In the present embodiment, in order to enable simultaneous communication with three PHS terminals 3, a 4ch DSP is used to process two ISDN lines (four B channels). The audio data received from the VoIP + LAN processing unit 11, that is, the audio data stored in the RTP packet is 64 kbit / s μ-law PCM / A-Law PCM (G.711) and 32 kbit / s ADPCM (G .726), 32 kbit / s Embedded ADPCM (G.727), 8 kbit / s CS-ACELP (G.729), and 6.3 / 5.3 kbit / s MP-MLQ / ACELP (G.723.1). And so on. In the present embodiment, the DSP 1321 converts any of the above-described types of audio data output from the VoIP + LAN processing unit 11 into 64 kbit / s μ-law PCM audio data, and outputs the audio data to the first adjustment buffer 1322. The audio data of 64 kbit / s μ-law PCM output from the second adjustment buffer 1323 is converted into any of the above types of audio data and output to the VoIP + LAN processing unit 11.
[0039]
The first adjustment buffer 1322 adjusts the output timing of audio data for each pair of B channels received from the DSP 1321 to the selector 134. The second adjustment buffer 1323 adjusts the output timing of the audio data for each pair of B channels received from the encoding / decoding unit 134 to the DSP 1321. In the present embodiment, the first adjustment buffer 1322 and the second adjustment buffer 1323 are built in the same FPGA (Field Programmable Gate Array) 14.
[0040]
The tone generating section 131 includes a melody IC 1311 and a tone ROM 1312. The melody IC 1311 can send out at least one melody (64 kbit / s μ-law PCM), generates a specified melody according to an instruction from the VoIP + LAN processing unit 11, and sends it to the selector 133. The tone ROM 1312 holds data of a plurality of types of local tones, reads out a designated tone (64 kbit / s μ-law PCM) and sends it to the selector 133 in accordance with an instruction from the VoIP + LAN processing unit 11.
[0041]
The selector 133 includes a selector circuit 1331. In accordance with an instruction from the VoIP + LAN processing unit 11, the selector circuit 1331 converts audio data for two ISDN lines (for four B channels) output from the first adjustment buffer 1322 in units of B channels. Whether to output the data as it is or to output the melody or tone output from the tone generator 131 is selected. In the present embodiment, the selector circuit 1331 is built in the FPGA 14.
[0042]
The encoding / decoding unit 134 includes an ADPCM transcoder 1341 and a CH codec 1342.
[0043]
ADPCM transcoder 1341 converts audio data for each pair of B channels of 64 kbit / s μ-law PCM output from selector 134 into audio data for each pair of B channels of 32 kbit / s ADPCM, and outputs CH data. Output to the codec 1342. Also, the audio data for each pair of B channels of 32 kbit / s ADPCM output from the CH codec 1342 is converted into audio data for each pair of B channels of 64 kbit / s μ-law PCM, and the second adjustment buffer 1323 Output to
[0044]
The CH codec 1342 performs wireless communication based on audio data (32 kbit / s ADPCM) for each pair of B channels output from the ADPCM transcoder 1341, that is, two ISDN lines (four B channels). The communication + communication control unit 12 causes each PHS terminal 3 to transmit a radio signal (voice signal) for each B channel. Also, based on a signal received from each PHS terminal 3 via the wireless communication + communication control unit 12, audio data (32 kbit / s ADPCM) for each pair of B channels, that is, two ISDN lines (B (For four channels) and outputs it to the ADPCM transcoder 1341. The CH codec 1342 has a function of generating a control signal of the amplification circuit and the modulation / demodulation circuit of the wireless communication + communication control unit 12, a function of scrambling / descrambling an audio signal, a function of generating / checking a CRC, a function of measuring a BER, a function of detecting a synchronization, and the like. It is a multifunctional LSI provided.
[0045]
The wireless communication + communication control unit 12 includes a wireless unit 125, an IF chip 121 that provides an interface function with the wireless unit 125, an EBI chip 122 that provides an internal interface function with a control data buffer 135, and a CPU 123. And a memory 124 that stores programs and data to be executed by the CPU 123 and functions as a work area for the CPU 123. Here, the IF chip 121, the EBI chip 122, the CPU 123, and the memory 124 are connected by an internal bus.
[0046]
The CPU 123 controls the wireless unit 125 based on control data and program data received via the control data buffer 135, and performs a call control process for communicating with the PHS terminal 3 and other processes.
[0047]
The wireless unit 125 is a unit for performing wireless communication with the PHS terminal 3 according to, for example, RCR STD-28 which is a standard of the PHS system for business use. Although not shown, a transmitting unit for outputting a radio wave to the PHS terminal 3, a receiving unit for receiving a radio wave from the PHS terminal 3, and a 1-GHz band for a desired frequency of 1.6 GHz. ^st 1 for generating a local signal ^st Local signal generation circuit and 233.15 MHz 2 ^nd 2 for generating a local signal ^nd It has a local signal generation circuit, a local signal switching circuit, and a modem that performs logical processing of π / 4 shift QPSK modulation. The transmission unit has, for example, a modulation circuit, a high-frequency amplification circuit, and an antenna circuit. The receiving unit includes, for example, an antenna circuit, a high-frequency amplifier, an intermediate-wave amplifier, a low-frequency amplifier, and a demodulator.
[0048]
The control data buffer 135 has a FIFO 1351. The FIFO 1351 is a bidirectional memory buffer, and transmits control data and program data from the CPU 113 of the VoIP + LAN processing unit 11 to the CPU 123 of the wireless communication + communication control unit 12, and transmits control data and program data from the CPU 123 of the wireless communication + communication control unit 12 to VoIP + LAN. It is used for transmitting to the CPU 113 of the processing unit 11. In this embodiment, the FIFO 1351 is built in the FPGA 14.
[0049]
Next, the flow of an IP packet sent from the IP-PBX 2 in the IP-compatible PHS base station device 1 having the above configuration will be described.
[0050]
The IP packet sent from the IP-PBX 2 stores the IP address assigned to the IP-PBX 2 as the source address of the IP header, and stores the IP address assigned to the IP-compatible PHS base station device 1 as the destination address. Is done. Also, the transmission port number of the IP-PBX 2 is stored as the source port number of the UDP (or TCP) header of this IP packet, and assigned to the B channel, the D channel and the IP-compatible PHS base station device 1 as the destination port number. One of the port numbers is stored. Here, among the four B channels of the two ISDN lines, three B channels used for communication with the PHS terminal 3 are assigned port numbers, but the remaining one B channel is used for controlling the radio section. The port number is not assigned because it is used as a packet for communication.
[0051]
Now, in the VoIP + LAN processing unit 11, the CPU 113 sorts the output destination of the data stored in the IP packet based on the destination port number of the UDP (or TCP) header of the IP packet sent from the IP-PBX2.
[0052]
Specifically, when the destination port number is a port number assigned to the B channel or no port number, CPU 113 outputs data stored in the IP packet to audio data processing section 132. This data is processed by the audio data processing unit 132, the selector 133, and the encoding / decoding unit 134 as data of the B channel specified by the destination port number (64 kbit / s PCM audio encoding and 32 kbit / s ADPCM voice encoding). After that, the data of the four B channels (32 kbit / s ADPCM data) is transmitted from the wireless unit 125 by 4 ch TDMA-TDD (Time Division Multiple Access-Time Division Duplex). The PHS terminal 3 transmits and receives radio waves corresponding to the B channel assigned to the PHS terminal 3 and performs a telephone conversation. In addition, it controls the wireless section by transmitting and receiving a radio wave corresponding to the B channel allocated to the control packet for the wireless section.
[0053]
If the destination port number is a port number assigned to the D channel, the CPU 113 outputs the data stored in the IP packet to the control data buffer 135. This data is sent to the wireless communication + communication control unit 12 via the control data buffer 135 (FIFO 1351). As a result, transmission and reception of D-channel information of the call control procedure specified by the standard (RCR STD-28) of the PHS system for business use can be performed between the IP-PBX 2 and the PHX terminal 3.
[0054]
When the destination port number is a port number assigned to the IP-compatible PHS base station device 1, CPU 113 extracts a tone transmission start instruction and a tone transmission stop instruction from the IP packet. The tone generator 131 and the selector 134 are controlled according to the extracted instruction. Specifically, in the case of a tone transmission start instruction, the tone generation unit 131 is controlled to output the tone of the type included in the tone transmission start instruction. At the same time, for the B channel specified by the port number included in the tone transmission start instruction, the tone output from the tone generation unit 131 instead of the audio data output from the audio data processing unit 132 is encoded. The selector 134 is controlled so as to be input to the decoding / decoding unit 134. In the case of the tone transmission stop instruction, the tone generation unit 131 is controlled so as to stop outputting the tone of the type included in the tone transmission stop instruction. At the same time, for the B channel specified by the port number included in the tone transmission start instruction, a selector is provided so that the audio data output from the audio data processing unit 132 is input to the encoding / decoding unit 134. 134 is controlled. In this way, transmission of a tone to the PHS terminal 3 can be controlled.
[0055]
Next, an operation of transmitting a hold tone or a local tone to the PHS terminal 3 in the office PHS system having the above configuration will be described.
[0056]
FIG. 3 is a diagram for explaining the operation when transmitting the hold tone and the SDT to the PHS terminal 3.
[0057]
It is assumed that a call is being made between two PHS terminals 3 (PHS terminal A and PHS terminal B) shown in FIG. 1 (S101).
[0058]
When the PHS terminal A is hooked or the hold button is pressed to shift to the hold state during a call (S102), the PHS terminal A sends a hooking signal (S103).
[0059]
In the IP-compatible PHS base station 1, upon receiving the hooking signal from the PHS terminal A, the wireless communication + communication control unit 12 transmits a hold request information signal including designation of a port number assigned to the B channel used by the PHS terminal A. Is generated and output to the VoIP + LAN processing unit 11 via the control data buffer 135. In response to this, the VoIP + LAN processing unit 11 generates an IP packet storing the information signal of the hold request and sends it to the IP-PBX 2 (S104).
[0060]
In the IP-PBX 2, when the main control unit 24 receives the information signal of the hold request via the VoIP + LAN processing unit 22, the PHS terminal using the B channel to which the port number included in the information signal is assigned A is specified, and further, a B channel used by the PHS terminal B during a call with the PHS terminal A is specified. Then, a tone transmission start signal (hold request information signal) including a port number assigned to the B channel used by the PHS terminal B and designation of a tone sound (hold tone) to be generated is generated, and this tone transmission is performed. The IP packet of the start signal is transmitted from the VoIP + LAN processing unit 22 to the IP-compatible PHS base station 1 (S105). Further, the main control unit 24 generates a tone transmission start signal (SDT request information signal) including a port number assigned to the B channel used by the PHS terminal A and designation of a tone sound (SDT) to be generated. Then, the IP packet of the tone transmission start signal is transmitted from the VoIP + LAN processing unit 11 to the IP-compatible PHS base station 1 (S108).
[0061]
In the IP-compatible PHS base station 1, when the VoIP + LAN processing unit 11 receives the IP packet of the tone transmission start signal (information signal of a hold request) from the IP-PBX 2, the VoIP + LAN processing unit 11 generates a tone sound designated by the tone transmission start signal. The tone generation unit 131 generates a certain holding tone. For the B channel to which the port number designated by the tone transmission start signal is assigned, the hold tone output from the tone generator 131 is selected instead of the audio data output from the audio data processor 132. The selector 133 is controlled in such a manner as to be performed (S106). Thereby, the hold sound is transmitted to PHS terminal B (S107).
[0062]
Further, in the IP-compatible PHS base station 1, when the VoIP + LAN processing unit 11 receives the IP packet of the tone transmission start signal (SDT request information signal) from the IP-PBX 2, the VoIP + LAN processing unit 11 outputs the tone specified by the tone transmission start signal. The tone generation unit 131 generates an SDT that is a sound. Also, for the B channel to which the port number specified by the tone transmission start signal is assigned, the SDT output from the tone generator 131 is selected instead of the audio data output from the audio data processor 132. Thus, the selector 133 is controlled (S109). Thereby, SDT is transmitted to PHS terminal A (S110).
[0063]
Next, in the hold state, when the PHS terminal A is hooked again or the hold button is pressed again to shift to the call state (S111), the PHS terminal A sends a hooking signal again (S112). .
[0064]
In the IP-compatible PHS base station 1, upon receiving the hooking signal again from the PHS terminal A, the wireless communication + communication control unit 12 issues a hold suspension request including the designation of the port number assigned to the B channel used by the PHS terminal A. An information signal is generated and output to the VoIP + LAN processing unit 11 via the control data buffer 135. In response to this, the VoIP + LAN processing unit 11 generates an IP packet storing the information signal of the suspension stop request, and sends it to the IP-PBX 2 (S113).
[0065]
In the IP-PBX 2, when the main control unit 24 receives the information signal of the suspension stop request via the VoIP + LAN processing unit 22, the PHS using the B channel to which the port number included in the information signal is allocated is used. The terminal A is specified, and further, the B channel used by the PHS terminal B during a call with the PHS terminal A is specified. Then, a tone transmission stop signal (a hold stop request information signal) including a port number assigned to the B channel used by the PHS terminal B and designation of a tone sound to be stopped (hold sound) is generated. The VoIP + LAN processing unit 22 transmits the IP packet of the transmission stop signal to the IP-compatible PHS base station 1 (S114). In addition, a tone transmission stop signal (SDT stop request information signal) including a port number assigned to the B channel used by the PHS terminal A and designation of a tone (SDT) to be stopped is generated, and the tone transmission is performed. The IP packet of the stop signal is transmitted from the VoIP + LAN processing unit 22 to the IP-compatible PHS base station 1 (S116).
[0066]
In the IP-compatible PHS base station 1, when the VoIP + LAN processing unit 11 receives the IP packet of the tone transmission stop signal (information signal of the suspension stop request) from the IP-PBX 2, the tone sound specified by the tone transmission stop signal is received. Is generated by the tone generating unit 131. Also, the selector 133 is controlled so that the audio data output from the audio data processing unit 132 is selected for the B channel to which the port number designated by the tone transmission stop signal is assigned (S115). Thereby, the voice from PHS terminal A is transmitted to PHS terminal B.
[0067]
In the IP-compatible PHS base station 1, when the VoIP + LAN processing unit 11 receives the IP packet of the tone transmission stop signal (SDT stop request information signal) from the IP-PBX 2, the VoIP + LAN processing unit 11 is designated by the tone transmission stop signal. The tone generation unit 131 stops generating the SDT as the tone sound. Also, the selector 133 is controlled so that the audio data output from the audio data processing unit 132 is selected for the B channel to which the port number designated by the tone transmission stop signal is assigned (S117). Thereby, the voice from PHS terminal B is transmitted to PHS terminal A.
[0068]
As described above, the state between the PHS terminal A and the PHS terminal B shifts to the communication state (S118).
[0069]
FIG. 4 is a diagram for explaining the operation when the extension DT is transmitted to the PHS terminal 3.
[0070]
When the PHS terminal 3 is off-hook to start a call (S201), a procedure for establishing a link in a wireless section is established between the PHS terminal 3 and the wireless communication + communication control unit 12 of the IP-compatible PHS base station device 1. It is executed (S202). Then, a procedure for call setting is disclosed among the PHS terminal 3, the IP-compatible PHS base station device 1, and the IP-PBX 2 (S203). At this time, the main control unit 24 of the IP-PBX 2 obtains information on the port number assigned to the B channel used by the PHS terminal 3 from the IP-compatible PHS base station device 1.
[0071]
By the way, in the IP-PBX 2, when the transmission timing of the extension DT comes, the main control unit 24 specifies the port number assigned to the B channel used by the PHS terminal 3 and the designation of the tone sound (extension DT) to be generated. A tone transmission start signal (extension DT transmission request) including the tone transmission start signal is generated, and the IP packet of the tone transmission start signal is transmitted from the VoIP + LAN processing unit 22 to the IP-compatible PHS base station 1 (S204).
[0072]
In the IP-compatible PHS base station 1, when the VoIP + LAN processing unit 11 receives the IP packet of the tone transmission start signal (extension DT transmission request) from the IP-PBX 2, the VoIP + LAN processing unit 11 outputs a tone sound specified by the tone transmission start signal. The extension DT is generated by the tone generator 131. For the B channel to which the port number designated by the tone transmission start signal is assigned, the hold tone output from the tone generator 131 is selected instead of the audio data output from the audio data processor 132. The selector 133 is controlled in such a manner as to be performed (S205). Thereby, the extension DT is transmitted to the PHS terminal 3 (S206).
[0073]
Next, when the called number of the first dial is input to the PHS terminal 3 (S207), the called number of the first dial is notified to the IP-PBX 2 via the PHS base station device 1 for IP (S208, S209).
[0074]
In the IP-PBX 2, when the main control unit 24 receives the called number of the first dial via the VoIP + LAN processing unit 22, the port number assigned to the B channel used by the PHS terminal 3 and the tone sound to be stopped A tone transmission stop signal (extension DT stop request) including the designation of (extension DT tone) is generated, and the IP packet of the tone transmission stop signal is transmitted from the VoIP + LAN processing unit 22 to the IP-compatible PHS base station 1 (S210). ).
[0075]
In the IP-compatible PHS base station 1, when the VoIP + LAN processing unit 11 receives the IP packet of the tone transmission stop signal (extension DT stop request) from the IP-PBX 2, the VoIP + LAN processing unit 11 outputs the tone sound specified by the tone transmission stop signal. The tone generation unit 131 stops generating the extension DT. The selector 133 is controlled so that the audio data output from the audio data processing unit 132 is selected for the B channel to which the port number specified by the tone transmission stop signal is assigned (S211).
[0076]
Hereinabove, one embodiment of the present invention has been described.
[0077]
According to the present embodiment, an instruction to start or stop sending a hold tone or a local tone is transmitted from the IP-PBX 2 to the IP-compatible PHS base station apparatus 1 via the IP network (LAN 4). Therefore, during the period when the hold tone or the local tone is being transmitted, the IP packet storing the hold tone or the local tone does not continue to flow in the IP network. For this reason, it is possible to suppress an increase in traffic on the IP network.
[0078]
Further, in the present embodiment, in the IP-compatible PHS base station apparatus 1, the CPUs 113 and 123 are respectively provided in the VoIP + LAN processing unit 11 for communicating with the IP network and the wireless communication + communication control unit 12 for communicating with the PHS terminal 3. Using a unit with A FIFO 1351 for relaying control and / or transmission and reception of program data between the CPU 113 of the VoIP + LAN processing unit 11 and the CPU 123 of the wireless communication + communication control unit 12 is provided. By doing so, an interface between the CPU 113 of the VoIP + LAN processing unit 11 and the CPU 123 of the wireless communication + communication control unit 12 can be realized with a simple configuration.
[0079]
The present invention is not limited to the above embodiment, and various modifications can be made within the scope of the invention.
[0080]
For example, in the above-described embodiment, the case where the IP-compatible PHS base station apparatus 1 generates a tone and transmits the tone to the PHS terminal 3 has been described using the hold tone, the SDT, and the extension DT as examples. However, the present invention is not limited to this. The present invention is applicable when transmitting various tones to the PHS terminal 3.
[0081]
In the above embodiment, the IP-PBX 2 may be connected to a plurality of IP-compatible PHS base station devices 1 via the LAN 4. In addition, various network terminals other than the IP-compatible PHS base station device 1 may be connected to the LAN 4. The line accommodated by the IP-PBX 2 is not limited to the ISDN line 5. For example, an analog telephone line may be used.
[0082]
Further, in the above embodiment, the case where the present invention is applied to an office PHS system has been described as an example, but the present invention can be widely applied to a wireless telephone system including an IP-PBX and an IP-compatible wireless base station device.
[0083]
【The invention's effect】
As described above, according to the present invention, it is possible to realize a wireless telephone system using an IP-PBX and an IP-compatible wireless base station device capable of suppressing an increase in traffic on an IP network.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of an office PHS system to which an embodiment of the invention is applied.
FIG. 2 is a diagram illustrating an example of a hardware configuration of an IP-compatible PHS base station device 1;
FIG. 3 is a diagram for explaining an operation when transmitting a hold tone and an SDT to a PHS terminal 3;
FIG. 4 is a diagram for explaining an operation when an extension DT is transmitted to a PHS terminal 3;
FIG. 5 is a schematic diagram of a conventional business PHS system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... IP compatible PHS base station apparatus, 2 ... IP-PBX, 3 ... PHS terminal, 4 ... LAN, 5 ... ISDN line, 11 ... VoIP + LAN processing part, 12 ... Wireless communication + Communication control unit, 13 logic unit, 14 FPGA, 21 ISDN line accommodation unit, 22 VoIP + LAN processing unit, 23 switch unit, 24 main control unit, 111, PHY, 112, EBI, 113, CPU, 114, memory, 131, tone generator, 132, audio data processor, 133, selector, 134,. Encoding / decoding unit, 135: control data buffer, 121: PHY, 122: EBI, 123: CPU, 124: memory, 125: wireless unit, 1311・ ・ Me De-IC, 1312 ... tone ROM, 1321 ... DSP, 1322 ... first adjustment buffer, 1323 ... second adjustment buffer, 1331 ... selector circuit, 1341 ... ADPCM transcoder, 1342 ... CH codec

Claims (8)

A wireless telephone system comprising: an IP-PBX (Internet Protocol-Private Branch Exchange); and an IP-compatible wireless base station apparatus that connects a wireless telephone to the IP-PBX via an IP network.
The IP-PBX is:
Instruction means for outputting an instruction to start and stop sending a hold tone or a local tone to the wireless telephone to the IP-compatible wireless base station apparatus via the IP network;
The IP-compatible wireless base station device includes:
Tone output means for outputting a music on hold and a local tone;
Selection control means for controlling transmission of a hold tone or a local tone output by the tone output means to the wireless telephone according to the instruction received from the IP-PBX via the IP network. Wireless telephone system. The wireless telephone system according to claim 1, wherein
The instruction means of the IP-PBX outputs to the IP-compatible wireless base station apparatus an instruction to start transmission of the hold sound in response to a hold request from a call partner of the wireless telephone, and In response to the hold release request, output an instruction to stop sending the hold sound to the IP-compatible wireless base station device,
The selection control unit of the IP-compatible wireless base station device, when receiving an instruction to start transmitting the hold tone from the IP-PBX, selects a hold tone output by the tone output unit and sends the hold tone to the wireless telephone. The wireless telephone system according to claim 1, wherein, when receiving the instruction to stop sending the holding sound, the selection output of the holding sound is stopped. The wireless telephone system according to claim 1, wherein
The instruction means of the IP-PBX outputs to the IP-compatible wireless base station apparatus an instruction to start sending an SDT (Special Dial Tone), which is one of the local tones, in response to a hold request from the wireless telephone. And in response to a hold release request from the wireless telephone, outputs an instruction to stop sending the SDT to the IP-compatible wireless base station apparatus;
The selection control means of the IP-compatible radio base station apparatus, when receiving an instruction to start transmission of the SDT from the IP-PBX, selects the SDT output by the tone output means and transmits it to the wireless telephone. A wireless telephone system for stopping the selective output of the SDT when receiving an instruction to stop the transmission of the SDT. The wireless telephone system according to claim 1, wherein
The instructing means of the IP-PBX, when it is time to start sending an extension DT (Dial Tone), which is one of the local tones, in response to a call setting request from the wireless telephone, An instruction to start transmission is output to the IP-compatible wireless base station device, and an instruction to stop sending the extension DT is output to the IP-compatible wireless base station device in response to the called number of the first dial from the wireless telephone. And
The selection control unit of the IP-compatible wireless base station device, when receiving an instruction to start transmission of the extension DT from the IP-PBX, selects the extension DT output by the tone output unit and sends the extension DT to the wireless telephone. The radio telephone system, wherein the transmission of the extension DT is stopped when the instruction to stop the transmission of the extension DT is received. An IP-compatible wireless base station device for connecting a wireless telephone to an IP-PBX (Internet Protocol-Private Branch Exchange) via an IP network,
Tone output means for outputting a music on hold and a local tone;
An instruction to start and stop sending a hold tone or a local tone to the wireless telephone is received from the IP-PBX via the IP network, and in accordance with the received instruction, the hold tone or the local tone output by the tone output means is output. Selection control means for controlling transmission of tones to the wireless telephone. An IP-compatible wireless base station apparatus. The IP-compatible wireless base station device according to claim 5, wherein
An IP communication processing unit including a CPU and communicating with the IP network;
A wireless communication processing unit that includes a CPU and performs communication with the wireless terminal;
An IP-compatible radio, further comprising a FIFO (First In First Out) for relaying control and / or transmission and reception of program data between the CPU of the IP communication processing means and the CPU of the wireless communication processing means. Base station device. An IP-PBX (Internet Protocol-Private Branch Exchange) accommodating an IP-compatible wireless base station device that connects a wireless telephone to an IP network via the IP network,
An IP-PBX comprising: an instruction unit for outputting an instruction to start and stop sending a hold tone or a local tone to the wireless telephone to the IP-compatible wireless base station device via the IP network. Hold in a wireless telephone system in a wireless telephone system including an IP-PBX (Internet Protocol-Private Branch Exchange) and an IP-compatible wireless base station apparatus that connects a wireless telephone to the IP-PBX via an IP network. A sound or local tone transmission method,
Outputting, by the IP-PBX, an instruction to start and stop transmitting a hold tone or a local tone to the wireless telephone to the IP-compatible wireless base station apparatus via the IP network;
Controlling the transmission of a hold tone or a local tone to the wireless telephone according to the instruction received from the IP-PBX via the IP network. How to send music on hold or local tones.

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