JP2005269663A - Communication apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To determine/recognize a DTMF sinal without fail with a communication apparatus (PBX) on a receiving side, even when transmitting the DTMF signal using a communication apparatus which performs voice sign compression. <P>SOLUTION: A communication apparatus 1 or 2 connected to a PBX 4 or 5 and a line 3 comprises a DTMF signal detecting portion 102 for detecting whether or not a DTMF signal is contained in a voice signal from the PBX 4 or 5; a DTMF signal monitoring portion 103; a DTMF cell generating portion 105 for coding and sending out a DTMF signal; a DTMF cell decomposing portion 110 for decoding a coded DTMF signal; and a DTMF signal generating portion 115 for generating a DTMF signal on the basis of the information content of a decoded DTMF signal and sending out this DTMF signal to the PBX 4 or 5. The transmission side communication apparatus 1 or 2 codes a DTMF signal in a specified form and transmits the DTMF signal, the reception side communication apparatus 1 or 2 decodes the coded DTMF signal and on the basis of this content information, and the DTMF signal is regenerated in the DTMF signal generating portion 115. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a push button (hereinafter referred to as “PB”) in a communication system in which a voice signal from a voice terminal device such as a telephone terminal device or a private branch exchange (hereinafter referred to as “PBX”) is compressed and transmitted. The present invention relates to a communication apparatus for accurately transmitting a dual tone multi frequency (hereinafter referred to as “DTMF”) signal including a signal.

2. Description of the Related Art Conventionally, in a communication system in which a voice signal is compressed and compressed by a communication device such as a multiplexing device and transmitted oppositely, a DTMF signal such as a PB signal sent from a telephone terminal device is also voiced in the same way as a normal voice signal The code was compressed and transmitted to the opposite communication device. That is, in the communication device on the transmission side, the DTMF signal is voice code compressed without special consideration and transmitted as a normal voice code compression signal, while in the communication device on the reception side, the received voice code compression signal Is expanded to a voice signal (DTMF signal), sent to a voice terminal device such as PBX, and the voice terminal device determines / recognizes the code of the DTMF signal and performs a predetermined operation. It was. Note that Patent Document 1 and Patent Document 2 are cited as related to the present technology.
JP-A-4-354495 Japanese Patent Laid-Open No. Sho 62-125726

  However, when the DTMF signal is compressed and expanded as one of the audio signals as in the prior art, the DTMF signal (audio signal) expanded by the receiving side communication device is out of the reception regulation, and the audio terminal device such as PBX On the other hand, there is a problem in that it is not recognized as a DTMF signal.

  Also, when transmitting a DTMF signal, a determination time for determining the DTMF signal is required on the side of the communication device that has received the DTMF signal, and during the determination time, the sound is transmitted to the opposite voice terminal device. On the side, after the DTMF sound obtained by expanding the voice code compression signal, the DTMF signal obtained by decoding the DTMF signal is reproduced, and the DTMF sound obtained by expanding the voice code compression signal may be outside the DTMF signal reception regulation. There is a problem that the voice terminal device such as PBX may not be recognized as a DTMF signal.

  An object of the present invention is to enable communication / determination of a DTMF signal without error in a receiving-side communication device (voice terminal device) even when a DTMF signal is transmitted using a communication device that performs voice code compression. To provide an apparatus.

  The present invention provides a communication apparatus connected to a communication line, a voice encoding unit that generates voice information by code-compressing an input voice signal, a DTMF detection unit that detects a DTMF signal from the voice signal, DTMF encoding means for generating DTMF information corresponding to the detected DTMF signal when a DTMF signal is detected by the DTMF detection means, transmission information including a header part and a first content information part, Transmission information including first transmission information or header and second content information parts in which the voice information generated by the voice encoding means is stored in the first content information part, and the DTMF encoding And an information output means for outputting the second transmission information in which the DTMF information generated by the means is stored in the second content information section to the communication line.

  In the communication device connected to the communication line, the present invention determines whether the reception information received from the communication line is first reception information including voice information or second reception information including DTMF information. And a voice decoding means for generating a voice signal by decoding the code-compressed voice information included in the first reception information when the discrimination means determines that the first reception information is determined. DTMF signal generating means for generating a DTMF signal based on DTMF information included in the second received information when the determining means determines that the received information is the second received information, and the speech decoding And an audio output means for outputting the audio signal generated by the means or the DTMF signal generated by the DTMF signal generation means.

  As described above, according to the present invention, in a communication system using speech code compression, a DTMF signal is encoded and transmitted, and the DTMF signal transmitted as speech is silenced to reproduce the DTMF signal within a specified value. Therefore, it becomes possible to transmit the DTMF signal without error.

  Therefore, even if voice terminal devices such as PBX are connected using a communication device having a voice code compression function such as an ATM multiplexing device, in addition to the operation of the voice mail device using the DTMF signal, transfer, voice guidance function, etc. It is possible to use the additional communication service function.

  Further, by adding a DTMF guard function to the DTMF signal monitoring unit, there is an effect of reducing the frequency of erroneously detecting a voice input as a DTMF signal.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a system configuration diagram showing the overall configuration of the present invention. In FIG. 1, this system includes one ATM multiplexer 1, the other ATM multiplexer 2, an ATM line 3 connecting the ATM multiplexer 1 and the ATM multiplexer 2, and an ATM multiplexer. PBX 4 connected to 1, PBX 5 connected to the ATM multiplexer 2, a plurality of extension telephones 44 accommodated in the PBX 4, a plurality of extension telephones 54 accommodated in the PBX 5, and an electronic mail apparatus 58 accommodated in the PBX 5 A public line 6 connecting the ATM multiplexer 1 and the ATM multiplexer 2, a centralized management terminal device 7 connected to the public line 6, and a management terminal device 8 connected to the ATM multiplexer 1 And a management terminal device 9 connected to the ATM multiplexer 2.

  The ATM multiplexing apparatus 1 compresses a series of voice signals from the PBX 4 into voice codes, converts them into ATM cells and transmits them to the ATM line 3, and decelerates the ATM cells received from the ATM line 3, This is subjected to voice code expansion, returned to a series of voice signals, and transmitted to the PBX 5. Similarly, the ATM multiplexer 2 compresses a series of voice signals from the PBX 5 into voice codes, converts them into ATM cells, transmits them to the ATM line 3, and decelerates the ATM cells received from the ATM line 3. After this, the voice code is decompressed, converted back to a series of voice signals, and transmitted to the PBX 4.

  The PBX 4 freely exchanges and connects between the extension telephones 44 or between the extension telephones 44 and the ATM multiplexer 1, and similarly, the PBX 5 is between the extension telephones 54 and between the extension telephones 54 and the ATM multiplexing apparatus 1. , The extension telephone 54 and the electronic mail device 58, or the ATM multiplexing device 2 and the electronic mail device 58 are freely exchanged and connected.

  To further explain this, the PBX 4 includes a speech path switch (SW) 41, an extension circuit (LIN) 43 connected to the speech path switch 41, a trunk circuit (TRK) 42 connected to the speech path switch 41, A central controller (CC) 45 and a main memory (MM) 46 are provided.

  The speech path switch 41 freely connects between the extension circuits 43 or between the extension circuit 43 and the trunk circuit 42 to set a speech path. The extension circuit 43 has an interface function for controlling connection of the extension telephone 44. The trunk circuit 42 has an interface function for controlling connection with the ATM multiplexer 1. Further, the central control unit 45 controls the entire PBX 4 including the communication path switch 41, the extension circuit 43, and the trunk circuit 42. The main storage unit 46 controls the entire PBX 4 by the central control unit 45. The necessary station data, tables, processing programs, etc. are stored.

  The PBX 5 is connected to the speech path switch (SW) 51, the extension circuit (LIN) 53 connected to the speech path switch 51, the trunk circuit (TRK) 52 connected to the speech path switch 51, and the speech path switch 51. A mail interface circuit (I / F) 57, a central control unit (CC) 55, and a main storage unit (MM) 56 are provided.

  The communication path switch 51 freely connects between the extension circuits 43, between the extension circuit 43 and the trunk circuit 42, between the extension circuit 54 and the mail interface circuit 57, or between the trunk circuit 52 and the mail interface circuit 57. In this case, a call path is set. The extension circuit 53 has an interface function for controlling connection to the extension telephone 54, the trunk circuit 52 has an interface function for controlling connection with the ATM multiplexer 2, and a mail interface circuit 57. Has an interface function for controlling connection with the electronic mail apparatus 58. Further, the central control unit 55 controls the entire PBX 5 including the communication path switch 51, the extension circuit 53, the trunk circuit 52, and the mail interface circuit 57. The main storage unit 56 includes the central control unit 55 of the PBX 5. It stores station data, tables, processing programs, and the like necessary for overall control.

  With such a configuration, the ATM multiplexer 1 and the ATM multiplexer 2 perform ATM communication via the ATM line 3. Therefore, between the extension telephone 44 and the extension telephone 54 or between the extension telephone 44 and the electronic mail apparatus 58, the PBX 4, the ATM multiplexing apparatus 1, the ATM line 3, the ATM multiplexing apparatus 2, and the PBX 5 are used. Voice signal communication connection (call connection) is possible.

  The central management terminal device 7 centrally manages the ATM multiplexing device 1 and the ATM multiplexing device 2 at a remote location, and the ATM multiplexing device 1 and the ATM multiplexing device via the public line 6. 2 is set, and various setting information necessary for the operation of the ATM multiplexer 1 and the ATM multiplexer 2 is set, and the communication state (failure information) of the ATM multiplexer 1 and the ATM multiplexer 2 is set. It is something to monitor.

  Further, the management terminal device 8 manages the ATM multiplexing device 1, sets various setting information necessary for the operation of the ATM multiplexing device 1, and also sets the communication state ( In the same manner, the management terminal device 9 manages the ATM multiplexer 2 and sets various setting information necessary for the operation of the ATM multiplexer 2. In addition, the communication state (failure information) of the ATM multiplexer 2 is monitored.

  FIG. 2 is a block diagram showing an internal configuration of the ATM multiplexing apparatus according to the embodiment of the present invention.

  In FIG. 2, the ATM multiplexer 1 and the ATM multiplexer 2 have the same configuration, and the ATM multiplexer 1 and the ATM multiplexer 2 are connected to each other with the trunk circuit interface units 101 and 201 and the DTMF signal. Detection units 102 and 202, DTMF signal monitoring units 103 and 203, voice code compression units 104 and 204, DTMF cell generation units 105 and 205, voice cell generation units 106 and 206, cell multiplexing units 107 and 207, ATM line interface units 108 and 208, cell separation units 109 and 209, DTMF cell decomposition units 110 and 210, voice cell decomposition units 111 and 211, output information switching units 112 and 212, and a DTMF signal generator 113. , 213, speech code decompression units 114 and 214, silence generation units 115 and 215, and selector (a) 116. And 216, is configured to include a selector (b) 117, 217.

  The trunk circuit interface units 101 and 201 are interface units for communicatively connecting audio signals with the PBXs 4 and 5 (trunk circuits 42 and 52), and the audio signals from the PBXs 4 and 5 are converted into DTMF signal detection units 102 and 202 and The voice signals are sent to the voice code compression units 104 and 204 and the voice signals from the selectors (b) 117 and 217 are sent to the PBXs 4 and 5.

  The DTMF signal detectors 102 and 202 detect whether or not the voice signal obtained from the trunk circuit interface units 101 and 201 includes a DTMF signal, and use the detected contents as a first DTMF detection signal to detect the DTMF signal. 103 and 203 and the DTMF cell generators 105 and 205, when the DTMF signal is detected, the first DTMF detection signal is continuously turned on, and the DTMF signal is not detected. Sometimes, the first DTMF detection signal is continuously turned off.

  The DTMF signal monitoring units 103 and 203 receive the DTMF signal transmitted through the DTMF signal detection units 102 and 202 and the first DTMF detection signal obtained from the DTMF signal detection units 102 and 202. Then, the obtained first DTMF detection signal is sampled, and from the immediately preceding signal change point (when changed from the on state to the off state, or when changed from the off state to the on state), the next (new The time until the signal change point is measured, and this is sent to the DTMF cell generation units 105 and 205 as signal change detection time information.

  The DTMF signal monitoring units 103 and 203 always detect and analyze the DTMF signal, and send the detection result and the analysis result to the DTMF cell generation units 105 and 205. That is, the detected content of the DTMF signal is sent as the second DTMF detection signal to the DTMF cell generators 105 and 205. When the DTMF signal is detected, the second DTMF detection signal is continuously turned on. In addition, when the DTMF signal is not detected, the second DTMF detection signal is continuously turned off, and DTMF signal value information (DTMF code information) is generated as a DTMF signal analysis result. This is notified to the sections 105 and 205.

  The DTMF signal monitoring units 103 and 203 receive DTMF signal status information indicating whether a DTMF signal is regularly detected or not detected at a predetermined interval (for example, 1 second interval). It has a function of notifying the cell generation units 105 and 205.

  The DTMF cell generation units 105 and 205 include a first DTMF detection signal obtained from the DTMF signal detection units 102 and 202, a signal change detection time information obtained from the DTMF signal monitoring units 103 and 203, a second DTMF detection signal, and An ATM cell is generated based on value information (DTMF code information) of a DTMF signal, and an ATM cell including identification information indicating the DTMF cell and content information of the DTMF signal is transmitted to the original DTMF signal. It is sent as information. The detailed configuration of the ATM cell (hereinafter referred to as “DTMF cell”) format for DTMF signal transmission will be described later.

  The voice code compression units 104 and 204 compress the voice signals obtained from the trunk circuit interface units 101 and 201 according to a predetermined rule and algorithm, and send the compressed voice signals to the voice cell generation units 106 and 206.

  The voice cell generators 106 and 206 receive the voice code-compressed voice signal from the voice code compressors 104 and 204 and generate an ATM cell based on the voice signal. The ATM cell including the content information of the voice signal compressed by voice code is transmitted as voice information. The detailed configuration of the ATM cell (hereinafter referred to as “voice cell”) format for voice signal transmission will be described later.

  The cell multiplexers 107 and 207 multiplex ATM cells from the DTMF cell generators 105 and 205 and the voice cell generators 106 and 206 in the order of generation, and transmit them to the ATM line interface units 108 and 208.

  The ATM line interface units 108 and 208 are physically, electrically, and logically matched with the ATM line 3 and send the ATM cells received from the cell multiplexing units 107 and 207 to the ATM line 3 as a counter device. The ATM cell is transmitted to the ATM multiplexing apparatus 1 or 2, and the ATM cell received from the ATM multiplexing apparatus 1 or 2 as the opposite apparatus via the ATM line 3 is transmitted to the cell separation units 109 and 209. Is.

  The cell separation units 109 and 209 recognize the cell types of the ATM cells received from the ATM line interface units 108 and 208, and classify them. If the ATM cell is a DTMF cell, the cell separation unit 109 and 209 separates the ATM cell from the DTMF cell decomposition. When the ATM cell is a voice cell, the ATM cell is sent to the voice cell decomposing units 111 and 211.

  Upon receiving the DTMF cell, the DTMF cell disassembling units 110 and 210 recognize whether the DTMF cell is a cell addressed to the own device, ATM header processing including cell missing determination (error detection), channel identification, and sequence number determination ( CPS-PH processing including error detection) is performed, and thereafter, the content information of the DTMF signal included in the received DTMF cell is recognized / analyzed, and the signal change detection time of the DTMF signal and the value information of the DTMF signal ( DTMF code information) is notified to the DTMF signal generators 113 and 213, and selector control signals for controlling the selectors (a) 116 and 216 and the selectors (b) 117 and 217 are notified to the output information switching units 112 and 212. To do.

  When receiving the voice cell, the voice cell decomposing units 111 and 211 perform ATM header processing and CPS-PH processing in the same manner as the DTMF cell decomposing units 110 and 210, and then extract a voice signal that has been subjected to voice code compression. This is sent to the voice code decompression units 114 and 214.

  The output information switching units 112 and 212 control the outputs of the selectors (a) 116 and 216 and the selectors (b) 117 and 217 based on the selector control signal received from the DTMF signal decomposition units 110 and 210. The content of the audio signal output to the PBXs 4 and 5 via the circuit interface units 101 and 201 is switched.

The DTMF signal generators 113 and 213 receive signal change detection time information and DTMF value information (DTMF code information) from the DTMF cell decomposition units 110 and 210, and receive DTMF signals corresponding to the DTMF value information (DTMF code information). The DTMF signal is generated and sent to the selectors (b) 117 and 217 for the same time as the time notified as the signal change detection time information.

  The voice code expansion units 114 and 214 perform voice code expansion on the voice signal compressed from the voice code received from the voice cell decomposition units 111 and 211, and send it to the selectors (a) 116 and 216.

  The silence generators 115 and 215 always generate silence signals and send them to the selectors (a) 116 and 216. Note that a silence signal is a signal that allows a person to feel a silence state without a sense of incongruity when a human listens to a sound, and a low-level noise signal is generally used.

  The selectors (a) 116 and 216 select either the audio signals from the audio code decompression units 114 and 214 or the silence signals from the silence generation units 115 and 215 according to the control from the output information switching units 112 and 212. b) Send to 177, 217.

  The selectors (b) 117 and 217 receive either the DTMF signals from the DTMF signal generators 113 and 213 or the voice signals or silent signals from the selectors (b) 177 and 217, respectively. To send to.

  Next, the format structure of the ATM cell used in the present invention will be described.

  FIG. 3 is a diagram showing a basic configuration of the ATM adaptation layer 2 (AAL2) cell format. In FIG. 3, the AAL2 cell includes a 5-byte ATM header part F301, a 1-byte start field (STF) part F302, and a 47-byte common field for storing specific content information of a voice signal or DTMF signal to be transferred. A path sublayer protocol data unit payload (CPS-PDU Payload) part F303 is included.

  The ATM header part F301 is an ITU-T recommendation I.D. As defined in 361 “Public Band ISDNATM Layer Specification”, a 4-bit GFC area, an 8-bit VPI area, a 16-bit VCI area, a 3-bit PT area, and a 1-bit CLP area , And an 8-bit HEC area.

  The STF part F302 stores a 6-bit OSF area for specifying the storage position of the common path sublayer protocol data unit part, a 1-bit SN area for storing the sequence number, and a parity pit. 1-bit P region. The configuration of the common path sublayer protocol data unit payload portion F303 in FIG. 3 will be described with reference to FIG.

  FIG. 4 is a diagram showing a format configuration of the common path sublayer protocol data unit payload portion F303 shown in FIG. 4A is a diagram showing a format configuration of a voice cell CPS-PDU payload unit used when transmitting voice signals such as voice and facsimile signals, and FIG. 4B is a diagram showing a DTMF signal and SS / SR signal. 2 is a diagram illustrating a format configuration of a CPS-PDU payload section for a DTMF cell used when transmitting a DTMF signal including a DTMF signal.

  In FIG. 4A, the voice cell CPS-PDU payload section is an ITU-T recommendation I.D. 363.2 "B-ISDN ATM adaptation layer type 2" is almost compliant, common path sublayer packet header (CPS-PH) part F401, and common path sublayer packet -It is comprised from the payload (CPS-PP) part F402.

  The CPS-PH unit F401 indicates a cell type, and stores an identifier “00” when the content of the audio signal to be transmitted is a normal audio signal, and an identifier “10” when the content of the audio signal is a facsimile signal. ", A 2-bit cell identification (VF) area for storing the channel identifier, a 6-bit channel identity (CID) area for storing the channel identifier, and a 6-bit length for storing information indicating the range of valid information. It consists of an indicator (LI) area, a 4-bit sequence number (SN) area for storing audio frame number information, and a 5-bit header error control (HEC) area for storing error control information. The common path sublayer packet payload portion F402 includes a voice code for storing a voice signal that has been voice code compressed. And it is configured as an information storage area. The voice cell including the voice cell CPS-PDU payload section is generated by the voice cell generation sections 106 and 206 shown in FIG.

  In FIG. 4B, this CPS-PDU Payload unit for DTMF cells is composed of a CPS-PH unit F403 and a CPS-PP unit F404, as in FIG. 4A.

  The CPS-PH unit F403 has the same configuration as the CPS-PH unit F401 in FIG. 4A. However, when the CPS-PDU Payload unit is for DTMF cells, the ATM cell is a DTMF cell in the VF area. In the CPS-PP part F404, an identifier “11” indicating that information on the DTMF audio signal or SS / SR signal information is stored is stored. Further, the CPS-PP unit F404 includes an SS / SR area for storing the SS / SR control signal, a signal change detection time (DTMF TIME) area for storing the signal change detection time measured by the DTMF signal monitoring units 103 and 203, and DTMF signal presence / absence (DV) area for storing presence / absence of DTMF signal and DTMF code (DTMF CODE) area for storing DTMF value information (DTMF code information). The DTMF cell including the DTMF cell CPS-PDU payload section is generated by the DTMF cell generation sections 105 and 205 shown in FIG.

  FIG. 5 is a diagram illustrating a specific configuration of the CPS-PP unit F404 in the CPS-PDU payload for the DTMF cell illustrated in FIG.

  In FIG. 5, an SS / SR area F501 is an SS / SR area that stores an SS / SR control signal that is a communication control signal used by the trunk circuit. The DTMF TIME area F502 is an area for storing the signal change detection time measured by the DTMF signal monitoring units 103 and 203 as described above, and is an area for storing time information from 0 to 126 ms. The DV area F503 is an area for storing the presence or absence of a DTMF signal as described above, and is an area in which “0” is stored when there is no signal and “1” is stored when there is a signal. is there.

  The DTMF CODE area F504 uses the upper 4 bits as a DTMF cell type area F504a for notifying DTMF cell type information, and the lower 4 bits for DTMF signal value information (DTMF code information). It is used as the code area F504b. That is, depending on the DTMF cell type area F504a, this DTMF cell is a DTMF on / off cell for sending a DTMF signal sending or stopping signal, a silent cell indicating that a silent signal is sent, or sending a silent signal It is notified whether the cell is a silent release cell indicating a stop. Further, the DTMF code area F504b notifies one of DTMF codes “0” to “9”, “*”, “#” or “A” to “D” of the DTMF signal. . A detailed description of the silence cell, silence release cell, and DTMF on / off cell will be described later.

  In FIG. 1, an extension telephone 44 accommodated in the PBX 4 accesses an electronic mail device 58 accommodated in the PBX 5, and the call is made via the PBX 4, the ATM multiplexer 1, the ATM line 3, the ATM multiplexer 2, and the PBX 5. In some cases, a connection is made and a PB signal that is one of the DTMF signals is sent from the extension telephone 44 to control the electronic mail apparatus 58.

  Hereinafter, taking such a case as an example, a DTMF signal transmission method for transmitting a DTMF signal from the PBX 4 side to the PBX 5 side will be described.

  FIG. 6 is an operation sequence diagram for explaining the first embodiment according to the operation of the DTMF transmission system of the present invention.

  In FIG. 2 and FIG. 6, when the voice signal from the extension telephone 44 is input to the ATM multiplexer 1 via the trunk 42 of the PBX 4, the ATM multiplexer 1 transmits the voice signal via the trunk circuit interface unit 101. The audio signal is input to the audio code compression unit 104 and the DTMF signal detection unit 102 as an input audio signal.

  In this embodiment, as an example, the input audio signal is an audio signal sent in the order of “audio 1”, “DTMF signal (audio 2)”, and “audio 3” as shown in FIG. explain.

  The voice code compression unit 104 performs voice code compression on any of “voice 1”, “DTMF signal (voice 2)”, and “voice 3” as voice signals. Therefore, since the DTMF signal (voice 2) is also processed as one voice signal, the voice signal that has been subjected to voice code compression is sent from the voice code compressor 104 to the voice cell generator 106 as shown in FIG. Here, it is assumed that the voice code compression unit 104 requires a processing time Va for the voice code compression process.

  The voice cell generation unit 106 sequentially creates the voice cell CPS-PDU payload shown in FIG. 4A based on the received voice code-compressed voice signal, and adds an ATM header and STF thereto. The voice cell is generated and sent to the cell multiplexing unit 107.

  On the other hand, the DTMF signal detection unit 102 receives an audio signal (input audio signal) and constantly monitors the signal content. Then, the DTMF signal is determined at the determination time Dt required for the DTMF determination. When the DTMF signal (voice 2) is received, the first DTMF detection signal is turned on and output.

  When the DTMF cell generation unit 105 recognizes the ON state of the first DTMF detection signal output from the DTMF signal detection unit 102, the DTMF cell generation unit 105 generates the DTMF cell CPS-PDU payload shown in FIG. In the DTMF CODE area F504 shown in DTMF CODE area F504, a silent cell code is stored, and an ATM header and STF are added to the DTMF cell type area F504a to generate a DTMF cell (hereinafter referred to as "silent cell"). The data is sent to the multiplexing unit 107.

  Further, the DTMF signal monitoring unit 103 samples the first DTMF detection signal from the DTMF signal detection unit 102 at, for example, 1 ms, detects the change point of the on / off state of the first DTMF detection signal, and changes the change Is detected (when changed from on to off, or when changed from off to on), the DTMF cell generation unit 105 is requested to transmit a DTMF cell. The DTMF signal monitoring unit 103 is set with a DTMF guard function. If the ON state for the preset guard time Gt or longer does not continue, the first DTMF detection signal changes from the OFF state to the ON state. Processing that is not considered changed.

  Therefore, when the DTMF signal detection unit 102 detects the DTMF signal (voice 2) as shown in FIG. 6 and continuously outputs the ON state of the first DTMF detection signal for the guard time Gt or longer, the DTMF signal monitoring unit 103 outputs the second DTMF detection signal as an ON state. At the same time, the DTMF signal monitoring unit 103 changes the first DTMF detection signal from the DTMF signal detection unit 102 from the on state to the off state from the point in time when the DTMF signal is detected (when the second DTMF detection signal is turned on). The signal change detection time obtained by adding the guard time Gt to the time until the time of change and the value information (DTMF code information) of the DTMF signal are notified to the DTMF cell generation unit 105.

  The guard time Gt is set (stored) in a flash ROM provided in the DTMF signal monitoring unit 103, and can be set as appropriate by the management terminal device 8 or the centralized management terminal device 7. However, a detailed description of this setting will be described later.

  The DTMF cell generation unit 105 recognizes that the second DTMF detection signal from the DTMF signal monitoring unit 103 has changed to the ON state, and also receives a signal change detection time and DTMF signal value information from the DTMF signal monitoring unit 103. When the DTMF code information) is received, the CPS-PDU Payload for DTMF cell shown in FIG. 4B is created, the signal change detection time is shown in the DTMF TIME area F502 shown in FIG. 5, and the DTMF signal is present in the DV area. Meaning “1” is stored in the DTMF cell type area F504a of the DTMF CODE area F504, the code indicating the DTMF on / off cell, and the DTMF code indicating the value of the received DTMF signal in the DTMF code area F504b. An ATM header and STF are added to the DTMF cell (hereinafter referred to as “DTMF Referred to as a cell. ") It generates, and sends this to the cell multiplexing section 107.

  The DTMF signal detection unit 102 recognizes that the DTMF signal has not been detected, changes the first DTMF detection signal from the ON state to the OFF state, and the DTMF cell generation unit 105 sets the first DTMF detection signal to the OFF state. When the change is detected, the CPS-PDU payload for DTMF cell shown in FIG. 4B is created, and the code of the silence canceling cell is stored in the DTMF cell type area F504a of the DTMF CODE area F504 shown in FIG. Then, an ATM header and STF are added thereto to generate a DTMF cell (hereinafter referred to as “silence canceling cell”), which is transmitted to the cell multiplexing unit 107.

  Further, the DTMF signal monitoring unit 103 recognizes that the DTMF signal has not been detected, changes the second DTMF detection signal from the ON state to the OFF state, and the DTMF cell generation unit 105 sets the second DTMF detection signal to the OFF state. 4C, the CPS-PDU Payload for the DTMF cell shown in FIG. 4B is created, and “0” meaning no DTMF signal is shown in the DV area shown in FIG. 5, and the DTMFCODE area F504 is created. A code indicating a DTMF on / off cell is stored in the DTMF cell type area F504a, and an ATM header and STF are added to the code to generate a DTMF cell (hereinafter referred to as "DTMF off cell"). Send it out.

  In the cell multiplexing unit 107, the ATM cells (DTMF cells or voice cells) generated by the DTMF cell generation unit 105 and the voice cell generation unit 106 are opposed to each other through the ATM line interface unit 108 and the ATM line 3 in the order of cell transmission request. To the ATM multiplexer 2 to be transmitted. When cell transmission requests are generated from the DTMF cell generation unit 105 and the voice cell generation unit 106 at the same time, the DTMF cell from the DTMF cell generation unit 105 is processed with priority. Accordingly, voice cells are continuously transmitted from (a) of FIG. 6 from the ATM multiplexing apparatus 1, but at the time (b) during the transmission, a silent cell, at a time (c) a DTMF on-cell, at a time ( The silent release cell is sent out at 2), and the DTMF off cell is sent out at the time (e).

  Next, the operation on the ATM multiplexing apparatus 2 side on the ATM cell receiving side will be described.

  The ATM multiplexer 2 receives an ATM cell (voice cell or DTMF cell) after a transmission delay time D by a relay line or the like.

  When the cell separation unit 209 receives the ATM cell via the ATM line interface unit 208, the cell separation unit 209 displays the information stored in the VF area in the CPS-PH unit F401 of the ATM cell shown in FIG. 4 (a) or (b). The read and received ATM cell is discriminated whether it is a voice cell or a DTMF cell, and if it is a voice cell, the received ATM cell is sent out to the voice cell decomposing unit 211, and if it is a DTMF cell, this The received ATM cell is sent out to the DTMF cell disassembly unit 210.

  Upon receiving a voice cell (received voice cell), the voice cell decomposition unit 211 performs ATM header processing, CPS-PH processing, etc., extracts a voice signal that has been subjected to voice code compression, and sends this to the voice code decompression unit 214. Send it out.

  When the voice code decompression unit 214 receives the voice signal subjected to the voice code compression, the voice code decompression unit 214 decodes / decompresses the voice signal and transmits it to the selector (a) 216 as an output of the voice code decompression unit. Here, decoding / decompression requires a decoding processing time Vb.

  On the other hand, when the DTMF cell decomposition unit 210 receives the DTMF cell transmitted at the time (b) in FIG. 6 and recognizes that it is a silent cell, the output information switching unit 212 is instructed to switch the selector (a) 216. I do. That is, the output information switching unit 212 recognizes that the silence cell has arrived, and switches the selector (a) 216 so that the output of the selector (a) 216 becomes a silence signal sent from the silence generation unit 215.

  Next, when the DTMF cell disassembly unit 210 receives the DTMF cell transmitted at the time (c) in FIG. 6 and recognizes that this is a DTMF on-cell, the output information switching unit 212 switches the selector (b) 217. Give instructions. That is, the output information switching unit 212 recognizes that the DTMF on-cell has arrived, and switches the selector (b) 217 so that the output of the selector (b) 217 becomes the DTMF signal sent from the DTMF signal generation unit 213. .

  At the same time, the DTMF cell disassembling unit 210 notifies the DTMF signal generating unit 213 of the signal change detection time and the value information (DTMF code information) of the DTMF signal included in the received DTMF on-cell, and includes these information contents. A corresponding DTMF code is generated and instructed to be transmitted as an output of the DTMF signal generator. Accordingly, at this time, the selector (b) 217 reproduces and outputs a DTMF signal corresponding to the signal change detection time and the value information (DTMF code information) of the DTMF signal included in the received DTMF on-cell.

  Next, when the DTMF cell disassembling unit 210 receives the DTMF cell transmitted at time (2) in FIG. 6 and recognizes that it is a silence canceling cell, the output information switching unit 212 receives the selector (a) 216. Instruct switching. That is, the output information switching unit 212 recognizes that the silence cancellation cell has arrived, and sets the selector (a) 217 so that the output of the selector (a) 216 becomes the audio signal sent from the audio code decompression unit 214. Switch.

  When the DTMF cell disassembling unit 210 receives the DTMF cell transmitted at the time (e) in FIG. 6 and recognizes that this is a DTMF off-cell, the output information switching unit 212 receives the selector (a) 216 and the selector ( b) Instruct 217 switching. That is, the output information switching unit 212 recognizes that the DTMF off-cell has arrived, causes the output of the selector (a) 216 to be a silence signal generated by the silence generation unit 215, and the output of the selector (b) 217 is The silent signal is output from the selector (b) 217 so that the output from the selector (a) 216 is obtained. Then, the output information switching unit 212 counts that the silent signal is transmitted from the selector (b) 217 for a certain time Et by a timer, and then switches the selector (a) 216 to switch from the selector (b) 217. The selector (b) 217 is switched so that the output is the output from the selector (a) 216 (the audio signal output from the audio code expansion unit 214).

  The fixed time Et is for preventing echo caused by the DTMF signal transmitted from the DTMF signal generator 213.

  With the above operation, the output from the selector (b) 217 becomes the output audio signal shown in FIG. 6, and this output audio signal is transmitted to the PBX via the trunk circuit interface unit 201. Therefore, the DTMF signal can be accurately transmitted without the DTMF signal compressed / decompressed by voice being input to the voice terminal device such as PBX.

  Next, a configuration and method for setting the guard time Gt in the DTMF signal monitoring unit 103 will be described.

  FIG. 8 is a diagram showing a system configuration and an ATM multiplexing device configuration that can arbitrarily set the guard time Gt.

  In FIG. 8, the ATM multiplexing apparatus 1 is provided with the DTMF signal monitoring unit 103 as described above, and the DTMF signal monitoring unit 103 has a flash ROM (F-ROM) for storing the guard time Gt. 103a is provided. In addition, the ATM multiplexing apparatus 1 includes an ATM multiplexing apparatus management section 118, a management terminal interface section 119 that interfaces with the management terminal apparatus 8, and a public interface that interfaces with the public line 6 such as ISDN. A line interface unit 120 is provided.

  The ATM multiplexer management unit 118 has a function of writing (or rewriting the content) to the flash ROM 103a in the DTMF signal monitoring unit 103, and this is added to the management terminal interface unit 119. It operates in response to a setting operation from the connected management terminal device 8 or the public line interface unit 120 and the centralized management terminal device 7 connected via the public line 6. That is, by manually operating the centralized management terminal device 7 or the management terminal device 8, it is possible to set (store) the guard time Gt that is most suitable for the configuration of the entire system in the flash ROM 103a.

Similarly to the ATM multiplexer 1, the ATM multiplexer 2 is provided with a flash ROM (F-ROM) 203a for storing the guard time Gt in the DTMF signal monitoring unit 203. The flash ROM 203a includes a multiplexing device management unit 218, a management terminal interface unit 219 that interfaces with the management terminal device 9, and a public line interface unit 220 that interfaces with the public line 6 such as ISDN. The guard time Gt most suitable for the configuration of the entire system can be set (stored).

  In the present embodiment, any one of 30 ms (milliseconds), 40 ms, 50 ms, 60 ms, 80 ms, 100 ms, 120 ms, 150 ms, 180 ms, 200 ms, or 250 ms can be selectively set as the guard time Gt. It is configured as follows. As described above, by appropriately setting the guard time Gt, it is possible to adapt to various communication standards, and in the case of a communication standard in which the transmission / reception time specification of the DTMF signal is specified as 45 ms or more, processing is required. If the guard time Gt is set to 40 ms taking the delay time into consideration, the communication standard can be met.

  In addition, when the DTMF signal transmission time of the connected voice terminal is guaranteed to be, for example, 100 ms or more, the guard time Gt can be set to a large value such as 100 ms. Even if the frequency component of the DTMF signal is included in the input of the real voice or the frequency component approximate to the frequency component of the DTMF signal is included, there is a probability that this will be erroneously detected as a DTMF signal. It becomes extremely small and the reliability of operation can be improved.

  Further, since the guard time Gt can be set by the centralized management device 7 installed at a remote place, the value can be easily changed even after the system enters the operation state, and the guard time Gt is also related to voice input. Even if a phenomenon of erroneous detection as a DTMF signal occurs, the central control device 7 is used to quickly change the value of the guard time Gt more rapidly from a remote location and erroneously detect the voice input as a DTMF signal. Serviceability is improved because it can be avoided.

  The guard time Gt can be switched between a value (basic value) used during call connection and a value used during a call. Therefore, in order to perform call connection processing quickly at the time of call connection, in the communication standard in which the transmission / reception time specification of the DTMF signal is specified to be 45 ms or more, the transmission time of the DTMF signal is 45 ms or more, The guard time Gt is set to 40 ms so as to be the minimum time conforming to the communication standard, and the value of the guard time Gt is set to prevent the voice signal from being erroneously detected as a DTMF signal during a call. It can be increased to 100 ms.

  Further, in the DTMF signal monitoring unit 103, when the guard time Gt is not set in the flash ROM 103a or in the case of a call connection, the guard time Gt is set to a minimum value (for example, 40 ms) suitable for the communication standard of the DTMF signal transmission / reception time. The system setting from the centralized management terminal device 7 or the management terminal device 8 can be performed efficiently.

  Next, the operation of the second embodiment when the DTMF guard function is not set in the DTMF signal monitoring unit 103 of the ATM multiplexing apparatus 1 will be described.

  FIG. 7 is an operation sequence diagram for explaining the second embodiment according to the operation of the DTMF transmission system of the present invention.

  2 and 7, the speech code compression unit 104 performs speech code compression on all of “speech 1”, “DTMF signal (speech 2)”, and “speech 3” as speech signals, as shown in FIG. As described above, the audio signal subjected to the audio code compression is transmitted from the audio code compression unit 104 to the audio cell generation unit 106. Here, it is assumed that the voice code compression unit 104 requires a processing time Va for the voice code compression process.

  The DTMF signal detection unit 102 receives an audio signal (input audio signal) and constantly monitors the signal content. Then, the DTMF signal is determined at the determination time Dt required for the DTMF determination, and when the DTMF signal (voice 2) is received, the first DTMF detection signal is turned on.

  On the other hand, when the DTMF cell generation unit 105 recognizes from the DTMF signal detection unit 102 that the first DTMF detection signal has changed to the ON state, it generates a silent cell and sends this to the cell multiplexing unit 107.

  Further, when the DTMF signal detection unit 102 detects the DTMF signal (voice 2) as shown in FIG. 7, the DTMF signal monitoring unit 103 also detects the DTMF signal (voice 2) almost simultaneously, so that the second DTMF is detected. The detection signal is changed from the on state to the off state, and the signal change detection time and DTMF value information (DTMF code information) are notified to the DTMF cell generation unit 105.

  The DTMF cell generation unit 105 recognizes that the second DTMF detection signal from the DTMF signal monitoring unit 103 has changed to the ON state, and also receives a signal change detection time and DTMF signal value information from the DTMF signal monitoring unit 103. When the DTMF code information) is received, the signal change detection time is indicated in the DTMF TIME area F502 shown in FIG. A DTMF on-cell storing a code indicating an on / off cell and further storing a DTMF code indicating the value of the received DTMF signal in the DTMF code area F504b is generated and transmitted to the cell multiplexing unit 107.

  In addition, the DTMF signal detection unit 102 recognizes that the DTMF signal has not been detected, changes the first DTMF detection signal from the on state to the off state, and the DTMF cell generation unit 105 turns off the first DTMF detection signal. Is detected, a silent release cell is generated and sent to the cell multiplexer 107.

  Further, the DTMF signal monitoring unit 103 recognizes that the DTMF signal has not been detected, changes the second DTMF detection signal from the on state to the off state, and the DTMF cell generation unit 105 turns off the second DTMF detection signal. Is detected, a DTMF off-cell is generated and sent to the cell multiplexing unit 107.

  In the cell multiplexing unit 107, as described above, the ATM line interface unit 108 and the ATM line 3 are arranged in the order of cell transmission request for the ATM cells (DTMF cells or voice cells) generated by the DTMF cell generation unit 105 and the voice cell generation unit 106. Is transmitted to the opposite ATM multiplexer 2 via the. When cell transmission requests are generated from the DTMF cell generation unit 105 and the voice cell generation unit 106 at the same time, the DTMF cell from the DTMF cell generation unit 105 is processed with priority. Accordingly, voice cells are continuously transmitted from the ATM multiplexing apparatus 1 from (f) in FIG. 7, but a silent cell and a DTMF on-cell are transmitted at the time (g) during the transmission, and the time (h) Thus, the silence canceling cell and the DTMF off cell are transmitted.

  Next, the operation on the ATM multiplexing apparatus 2 side on the ATM cell receiving side will be described.

  The ATM multiplexer 2 receives an ATM cell (voice cell or DTMF cell) after a transmission delay time D by a relay line or the like.

  When the cell separation unit 209 receives the ATM cell via the ATM line interface unit 208, the cell separation unit 209 determines whether the received ATM cell is a voice cell or a DTMF cell. The received ATM cell is sent to the voice cell decomposing unit 211. If it is a DTMF cell, the received ATM cell is sent to the DTMF cell decomposing unit 210.

  Upon receiving a voice cell (received voice cell), the voice cell decomposition unit 211 performs ATM header processing, CPS-PH processing, etc., extracts a voice signal that has been subjected to voice code compression, and sends this to the voice code decompression unit 214. Send it out.

  When the voice code decompression unit 214 receives the voice signal subjected to the voice code compression, the voice code decompression unit 214 decodes the voice signal and transmits it to the selector (a) 216 as an output of the voice code decompression unit. Here, the decoding process time Vb is required for decoding.

  On the other hand, when the DTMF cell disassembling unit 210 recognizes the silent cell and the DTMF on-cell transmitted at time (g) in FIG. 7, the output information switching unit 212 is instructed to switch the selector (a) 216 and the selector (b) 217. So that the output from the selector (a) 216 becomes a silence signal sent from the silence generator 215, and the output from the selector (b) 217 becomes a DTMF signal sent from the DTMF signal generator 213. To be.

  At the same time, the DTMF cell decomposition unit 210 notifies the DTMF signal generator 213 of the signal change detection time and the value information (DTMF code information) of the DTMF signal included in the DTMF on-cell received by the DTMF signal generator 213. The DTMF code corresponding to these information contents is generated and instructed to be transmitted as the output of the DTMF signal generator. Accordingly, at this time, the selector (b) 217 outputs a DTMF signal corresponding to the signal change detection time and the value information (DTMF code information) of the DTMF signal included in the received DTMF on-cell.

  Next, when the DTMF cell disassembling unit 210 recognizes the silence release cell and the DTMF off cell transmitted at the time (H) in FIG. 7, it instructs the output information switching unit 212 to switch the selector (b) 217, and the selector (B) The silencer signal is sent from the selector (b) 217 so that the output of the selector 217 becomes the output from the selector (a) 216.

  In addition, the output information switching unit 212 counts that a certain time Et has elapsed since recognition of reception of the DTMF off-cell, and thereafter switches the selector (a) 216 so that the output of the selector (b) 217 is The selector (b) 217 is switched so that the output from the selector (a) 216 (the audio signal output from the audio code expansion unit 214) is obtained.

  With the above operation, the output from the selector (b) 217 becomes the output audio signal shown in FIG. 7, and this output audio signal is transmitted to the PBX via the trunk circuit interface unit 201. Therefore, a DTMF signal can be accurately transmitted in a short time without the DTMF signal compressed / decompressed by voice being input to a voice terminal device such as PBX.

  In this way, not only the voice signal but also the DTMF signal can be accurately transmitted from the extension telephone 44 of the PBX 4 to the voice mail apparatus 58.

  Note that, as described above, the DTMF signal monitoring units 103 and 203 indicate whether the DTMF signal is regularly detected or not detected at a predetermined interval (for example, every 1 second). It has a function of notifying signal state information to the DTMF cell generators 105 and 205. Then, the DTMF cell generators 105 and 205 transmit a DTMF on-cell or a DTMF off-cell based on this notification.

  This function is necessary in the embodiment of the present invention because the ATM multiplexing apparatus that has received the DTMF on-cell is configured to receive the DTMF off-cell and stop the DTMF signal after transmitting the DTMF signal. Is. That is, it prevents a state in which a DTMF off-cell is lost on the ATM line due to a failure or malfunction of the ATM line and the ATM multiplexing apparatus cannot receive the DTMF off-cell and continues to send out the DTMF signal.

1 is a system configuration diagram showing an overall configuration of the present invention. It is a block diagram which shows the internal structure of the ATM multiplexing apparatus concerning embodiment of this invention. It is a figure which shows the basic composition of ATM cell AAL2 format. FIG. 4 is a diagram illustrating a configuration of a common path sublayer protocol data unit payload portion illustrated in FIG. 3. It is a figure which shows the specific structure of the common path sublayer packet payload part for DTMF cells. It is an operation | movement sequence diagram explaining 1st Embodiment concerning operation | movement of the DTMF transmission system of this invention. It is an operation | movement sequence diagram explaining 2nd Embodiment concerning operation | movement of the DTMF transmission system of this invention. It is a figure which shows the structure of the system which makes it possible to set arbitrarily the guard time of a DTMF signal monitoring part, and the structure of an ATM multiplexing apparatus.

Explanation of symbols

1, 2: ATM multiplexer 3: ATM line 4, 5: PBX
6: Public line 7: Centralized management terminal device 8, 9: Management terminal device 101, 201: Trunk circuit interface unit 102, 202: DTMF signal detection unit 103, 203: DTMF signal monitoring unit 104, 204: Voice code compression unit 105 , 205: DTMF cell generation unit 106, 206: Voice cell generation unit 107, 207: Cell multiplexing unit 108, 208: ATM line interface unit 109, 209: Cell separation unit 110, 210: DTMF cell decomposition unit 111, 211: Voice Cell decomposition unit 112, 212: Output information switching unit 113, 213: DTMF generation unit 114, 214: Speech code expansion unit 115, 215: Silence generation unit 116, 216: Selector (a)
117, 217: selector (b)

Claims (7)

In a communication device connected to a communication line,
Voice encoding means for generating voice information by code-compressing an input voice signal;
DTMF detection means for detecting a DTMF signal from the audio signal;
DTMF encoding means for generating DTMF information in accordance with the detected DTMF signal when the DTMF signal is detected by the DTMF detection means;
Transmission information including a header part and a first content information part, wherein the first transmission information or the header part and the voice part generated by the voice encoding means are stored in the first content information part. Transmission information including two content information sections, information for outputting the second transmission information in which the DTMF information generated by the DTMF encoding means is stored in the second content information section to the communication line. Output means;
A communication apparatus comprising: The first transmission information and the second transmission information are cells;
3. The communication apparatus according to claim 1, wherein the information output unit outputs the cell to the communication line. The DTMF information is
3. The communication apparatus according to claim 1, further comprising DTMF code information indicating a code of the DTMF signal and time information indicating a signal detection time of the DTMF signal. The DTMF detection means includes
Measuring means for measuring a signal detection time of the DTMF signal;
Analyzing means for analyzing the code of the DTMF signal;
The DTMF encoding means includes:
Generating the time information based on the measurement result of the measurement means, generating the DTMF code information based on the analysis result of the analysis means, and generating the DTMF information including the time information and the DTMF code information. The communication device according to claim 3. In a communication device connected to a communication line,
Discrimination means for discriminating whether the reception information received from the communication line is first reception information including voice information or second reception information including DTMF information;
Audio decoding means for decoding the code-compressed audio information included in the first reception information to generate an audio signal when the determination means determines that the first reception information is;
DTMF signal generation means for generating a DTMF signal based on DTMF information included in the second reception information when the determination means determines that the second reception information is present;
Voice output means for outputting the voice signal generated by the voice decoding means or the DTMF signal generated by the DTMF signal generation means;
A communication apparatus comprising: The first transmission information and the second transmission information are cells;
6. The communication apparatus according to claim 5, further comprising a decelerating unit that decelerates the first transmission information and the second transmission information. The DTMF information is
DTMF code information indicating the code of the DTMF signal and time information indicating the signal detection time of the DTMF signal,
The DTMF signal generating means includes:
The communication apparatus according to claim 6, wherein a DTMF signal is generated based on the DTMF code information and time information stored in the DTMF information.

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