JP2006295526A - Packet multiplex transmission device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a packet multiplex transmission device in which the packet multiplex transmission device of a receiving side, can transmit IP packets in appropriate timing by multiplexing a plurality of packets which is discriminated as silent in the same channel into a short packet and transmitting, and at the same time, can improve transmission efficiency in the silent interval. <P>SOLUTION: The device discriminates voice/silent of voice data in a packet from a terminal, assembles a short packet from voice packet information, stores in a storage means, performs short packet assembling from silent packet information, and multiplexing using a short packet multiplexing means, multiplexes short packets from the storage means and the short packet multiplexing means, and transmits to a partner device. On the other hand, the device decomposes packets from the partner side, extracts the multiplexed short packets, discriminates silent compression of the packet, extracts short packet information carried out silent compression, assembles a packet from the information, and transmits to the terminal. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a packet multiplex transmission apparatus that packetizes and multiplexes an audio signal or the like and assembles and transmits the packet into one IP packet (hereinafter referred to as a multiplexed packet).

A conventional packet multiplex transmission device disclosed in Japanese Patent Application Laid-Open No. 2004-200791 receives IP packets transmitted from a plurality of VoIP (Voice over Internet Protocol) terminals, converts them into short packets, and then a plurality of shorts. The packets are multiplexed to assemble one IP packet (hereinafter referred to as multiplexed packet) and transmitted to the destination packet multiplexing transmission apparatus.
The destination packet multiplex transmission apparatus disassembles the received multiplexed packet into individual short packets, and then restores the original IP packet from each short packet and transmits it to the VoIP terminal as the final transfer destination. Since the header of the short packet is smaller than the header of the IP packet, the packet transmission amount can be reduced by applying the packet multiplexing transmission apparatus.

As a means for further reducing the amount of transmission, it is conceivable to apply silence compression in which the presence / absence of voice is determined and only voice data determined to be voice is transmitted. When general silence compression is applied to a packet multiplex transmission apparatus, only IP packets including voice data determined to be sound are transmitted as short packets. In this case, the destination packet multiplex transmission apparatus cannot determine whether the IP packet is discarded on the transmission path or is not transmitted because it is determined to be silent, and therefore, to the VoIP terminal that is the final transfer destination. There arises a problem that IP packets cannot be transmitted at an appropriate timing.
As a means for solving such a problem, it is conceivable to apply a silence compression method as disclosed in JP-A-2002-99299. In this method, since a flag indicating silence is transmitted when it is determined that there is no sound, all IP packets received from the VoIP terminal are transmitted as short packets regardless of whether the sound is determined to be sound or silent. Thus, the destination packet multiplex transmission apparatus can transmit the IP packet to the VoIP terminal as the final transfer destination at an appropriate timing.

Japanese Patent Laid-Open No. 2004-200791 JP 2002-99299 A

  When silence compression is applied to a packet multiplex transmission apparatus, a packet multiplex transmission apparatus on the receiving side can transmit an IP packet at an appropriate timing by always transmitting a packet even in the case of silence. However, since it is necessary to always transmit a packet even in the case of silence, there is a problem that the transmission efficiency in a silent section is lowered.

  The packet multiplex transmission apparatus according to the present invention multiplexes a plurality of packets determined to be silent on the same channel into a single short packet, and transmits the IP packet at an appropriate timing. An object is to improve transmission efficiency in a silent section while enabling transmission.

A packet multiplex transmission apparatus according to the present invention is:
A packet receiving means for receiving a packet from the terminal device;
Sound / silence determination means for determining the sound / silence of the voice data included in the packet received by the packet reception means;
Short packet assembling means for assembling a short packet from information of packets determined to be sound by the sound / silence determining means;
Short packet storage means for storing short packets assembled by the short packet assembly means;
Short packet multiplexing means for assembling and multiplexing short packets from information of packets determined to be silent by voice / silence determination means;
Multiplex packet assembling means for multiplexing short packets stored in short packet storage means and short packet multiplexing means,
Multiplexed packet transmitting means for transmitting the packet assembled by the multiplexed packet assembling means to the packet multiplex transmission apparatus at the other end,
Multiplexed packet receiving means for receiving a packet transmitted by the counterpart packet multiplex transmission device,
Multiplex packet decomposing means for decomposing the packet received by the multiplexed packet receiving means and taking out the multiplexed short packet;
Silence compression determination means for determining whether or not the short packet taken out by the multiplexed packet decomposition means is silently compressed,
Short packet separation means for decomposing a short packet determined to be silently compressed by the silence compression determination means and extracting information of the multiplexed short packets;
A packet assembling means for assembling a packet to be transmitted to the terminal device using the information of the short packet;
Packet transmitting means for transmitting the packet assembled by the packet assembling means to the terminal device is provided.

According to the present invention, when a plurality of packets determined to be silent on the same channel are assembled into one short packet by the short packet multiplexing means, multiplexed and transmitted, thereby transmitting voice data packets determined to be silent Since the increase in the overhead of header information can be reduced, the effect of improving the transmission efficiency in the silent period can be obtained.
Further, since all packets received from the terminal device are transmitted as short packets, the counterpart packet multiplexing transmission device can transmit the packet to its own terminal device at an appropriate timing.

Hereinafter, the best mode for carrying out the present invention will be described.
Embodiment 1 FIG.
1 is a block diagram showing a configuration of a packet multiplex transmission apparatus according to Embodiment 1 of the present invention. In this figure, 101 is an IP packet receiver that receives an IP packet transmitted from a VoIP terminal, 102 determines whether or not the voice data contained in the IP packet received by the IP packet receiver 101 can be silence-compressed, Furthermore, a voice / silence determination unit 103 for determining voice / sound of voice data, 103 is voice data determined by the voice / silence determination unit 102 to be silence-compressible or voice data determined to be voice and its IP A short packet assembly unit 104 generates a short packet from the packet header, and a buffer 104 stores the short packet generated by the short packet assembly unit 103.

  Reference numeral 105 denotes a noise code generation unit that converts voice data determined to be silent by the voice / silence determination unit 102 into a noise code. Reference numeral 106 denotes a noise code converted by the noise code generation unit 105 and silent data converted to the noise code. A short code is generated from the IP header of the packet and a noise code multiplexing unit 107 as a short packet multiplexing unit that multiplexes the noise code of the same channel into one short packet is stored in the short packet storage buffer 104 and the noise code multiplexing unit 106. Multiplexed packet assembling unit for multiplexing multiplexed short packets to create a multiplexed packet, and 108 for transmitting a multiplexed packet for transmitting the multiplexed packet created by multiplexed packet assembling unit 107 to the destination packet multiplexing transmission device Part.

  Reference numeral 109 denotes a multiplexed packet receiving unit that receives a multiplexed packet transmitted from the destination packet multiplexing transmission apparatus, and 110 denotes a multiplexing that decomposes the multiplexed packet received by the multiplexed packet receiving unit 109 into individual short packets. A non-compressed packet decomposing unit 111 is a silent compression determining unit that determines whether or not the short packet decomposed by the multiplexed packet decomposing unit 110 is silently compressed, and 112 is determined by the silent compression determining unit 111 to be silently compressed. It is determined whether or not the noise code included in the short packet is multiplexed. If the noise code is multiplexed, a noise code separation unit 113 that separates the noise code into individual noise codes is separated by the noise code separation unit 112. Noise signal generator 114 for generating audio data corresponding to the noise code, 114 is silence compression determination An IP packet is created from the short packet determined not to be silence-compressed at 111, and the IP data is generated from the voice data generated by the noise signal generator 113 and the header information of the short packet output from the noise code separator 112. An IP packet assembly unit 115 that creates a packet is an IP packet transmission unit 115 that transmits the IP packet created by the IP packet assembly unit 114 to the VoIP terminal.

Next, the operation will be described.
First, the operation when the packet multiplex transmission apparatus receives an IP packet from a VoIP terminal will be described. In this case, the packet multiplex transmission apparatus receives the IP packet from the VoIP terminal by the IP packet receiving unit 101, and outputs it to the voice / silence determination unit 102. The voice / silence determination unit 102 examines the IP packet input from the IP packet reception unit 101 and determines whether the voice data can be compressed with silence. For example, an RTP (Real-time Transport Protocol) header of an input IP packet is inspected, and voice data is converted into ITU (International Telecommunications Union) -T recommendation G.264. If it is encoded by a 711-compliant 64 kbit / s PCM (Pulse Coded Modulation) system, it is determined that silence compression is possible. If it is encoded by a method other than this, it is determined whether or not silence compression is performed. Furthermore, the voice / silence determination unit 102 determines whether or not the voice data is voice when the voice data included in the input IP packet can be silence-compressed. For example, the signal level of the voice data included in the input IP packet is calculated, and if the signal level is equal to or higher than a preset threshold value, the voice data is determined to be sound. When the voice / silence determination unit 102 determines that the voice data is voiced, the voice / silence determination unit 102 outputs the IP packet to the short packet assembly unit 103.

Next, the short packet assembly unit 103 creates a short packet from the IP packet input from the voice / silence determination unit 102. For example, only necessary information is extracted from the IP / UDP (User Datagram Protocol) / RTP header of the input IP packet to create header information of the short packet.
The format of the header information of the short packet is shown in FIG. As shown in this figure, the header information of the short packet is composed of a destination VoIP terminal address, a serial number, and an encoding type. The destination VoIP terminal address is the IP address of the VoIP terminal that transmits the IP packet, and the serial number is a numerical value that increases by 1 with respect to the short packet of the same transfer destination based on the sequence number (SN) of the RTP header. Give. The encoding type is obtained by encoding the type of audio data encoding method. Then, the short packet assembly unit 103 uses the payload of the RTP packet as the payload of the short packet, and stores the created short packet in the short packet accumulation buffer 104.

On the other hand, when the voice / silence determination unit 102 determines that the voice data is silent, the IP packet is output to the noise code generation unit 105. Then, the noise code generation unit 105 determines a noise code corresponding to the voice data of the input IP packet, and outputs the noise code and the IP packet to the noise code multiplexing unit 106. For example, the level of the voice signal is calculated from the voice data of the input IP packet, and a preset noise code is assigned according to the level of the voice signal.
Next, the noise code multiplexing unit 106 identifies a voice channel from the input IP packet, and determines whether or not a noise code of the same voice channel has already been accumulated. If noise codes of the same voice channel are not accumulated, a short packet is newly created from the input IP packet. For example, only necessary information is extracted from the IP / UDP / RTP header of the input IP packet to create the header information of the short packet shown in FIG. At this time, code information corresponding to the noise code is stored in the encoding type of the short packet header. The noise code multiplexing unit 106 stores the input noise code as a payload of a short packet.

  When noise codes of the same voice channel have already been accumulated, the coding type code information included in the short packet header that has already been accumulated is updated in accordance with the number of multiplexed noise codes. For example, an encoding type code is defined in a form corresponding to the number of multiplexed noise codes, and the corresponding code information is retrieved and stored in the encoding type area each time the noise code is multiplexed. Then, as shown in FIG. 3, the generated noise code is added to the end of the payload of the short packet.

  Next, the multiplexed packet assembling unit 107 calculates the total length of the short packets stored in the short packet storage buffer 104 and the short packets stored in the noise code multiplexing unit 106, and the calculated total length is calculated in advance. When the set threshold value is exceeded, the short packet stored in the short packet storage buffer 104 and the short packet stored in the noise code multiplexing unit 106 are multiplexed to create a multiplexed packet. Then, the multiplexed packet assembling unit 107 outputs the created multiplexed packet to the multiplexed packet transmitting unit 108, and the multiplexed packet transmitting unit 108 transmits the multiplexed packet to the counterpart packet multiplexing transmission device.

  Next, the operation when a multiplexed packet is received from the counterpart packet multiplexing transmission apparatus will be described. In this case, the packet multiplexing transmission apparatus receives the multiplexed packet transmitted from the counterpart packet multiplexing transmission apparatus by the multiplexed packet receiving unit 109 and outputs it to the multiplexed packet decomposing unit 110. Then, the multiplexed packet decomposing unit 110 decomposes the multiplexed packet input from the multiplexed packet receiving unit 109 into individual short packets and outputs the short packets to the silence compression determination unit 111 for each short packet. Next, the silence compression determining unit 111 refers to the header information of the short packet input from the multiplexed packet decomposing unit 110, and the payload of the short packet is determined as a noise code from the code information stored in the encoding type area. It is determined whether or not. When it is determined that the payload of the input short packet is not a noise code, the input short packet is output to the IP packet assembling unit 114. Then, the IP packet assembly unit 114 creates an IP packet from the short packet input from the silence compression determination unit 111. For example, an IP / UDP / RTP header is generated from the header information of the short packet, and the payload of the short packet is stored in the payload of the RTP packet.

  On the other hand, when the silence compression determination unit 111 determines that the payload of the short packet is a noise code, the silence compression determination unit 111 outputs the input short packet to the noise code separation unit 112. Then, the noise code separation unit 112 refers to the coding type included in the header information of the input short packet, and determines whether or not the noise code is multiplexed. For example, an encoding type code is defined in a form corresponding to the multiplexing number of the noise code, and the multiplexing number can be acquired from the encoding type value. If the noise code is not multiplexed, the noise code separation unit 112 outputs the noise code of the short packet to the noise signal generation unit 113 and outputs the short packet header to the IP packet assembly unit 114. If the noise code is multiplexed, the noise code at the head of the short packet is output to the noise signal generation unit 113 and the short packet header is output to the IP packet assembly unit 114. Next, the second stored noise code is output to the noise signal generation unit 113, the serial number included in the short packet header is incremented by 1, and then the short packet header is output to the IP packet assembly unit 114. Thereafter, each time one noise code is output, the serial number included in the short packet header is incremented by one and output.

Next, the noise signal generation unit 113 generates audio data corresponding to the input noise code. For example, audio data corresponding to each noise code is prepared in advance, and audio data corresponding to the input noise code is output. Next, the IP packet assembly unit 114 creates an IP packet from the short packet header output from the noise code separation unit 112 and the voice data output from the noise signal generation unit 113. For example, an IP / UDP / RTP header is created from the header information of the short packet, and the voice data input from the noise signal generation unit 113 is stored in the payload of the RTP packet.
Next, the IP packet assembling unit 114 outputs the created IP packet to the IP packet transmitting unit 115, and the IP packet transmitting unit 115 transmits the input IP packet to the VoIP terminal.

  As described above, according to the first embodiment of the present invention, when there are a plurality of noise codes of the same voice channel and these noise codes are multiplexed into the same IP packet, the noise code multiplexing unit 106 However, by assembling these noise codes as one short packet, it is possible to reduce an increase in overhead of header information when transmitting a packet of audio data determined to be silent, so that transmission efficiency in a silent interval is reduced. Is obtained.

  In Embodiment 1 of the present invention, since all IP packets received from the VoIP terminal are transmitted as short packets, the counterpart packet multiplexing transmission apparatus transmits the IP packet to the VoIP terminal at an appropriate timing. Is possible.

  In the first embodiment of the present invention, the voice / silence determination unit 102 determines that the received voice data of the IP packet is ITU-T recommendation G.264. Since it is determined that silence can be compressed only when encoding is performed according to the H.711 compliant 64 kbit / s PCM method, an effect that the silence compression processing can be easily implemented is obtained.

  In the first embodiment of the present invention, the multiplexed packet assembling unit 107 multiplexes the total length of the short packets stored in the short packet storage buffer 104 and the short packets stored in the noise code multiplexing unit 106. Therefore, it is possible to suppress the short packet transmission delay.

  Further, in Embodiment 1 of the present invention, the information regarding the multiplexing of the noise code is stored as the code information of the encoding type of the short packet header, but the payload length is stored in the short packet header, and the payload length This information may indicate that the noise code is multiplexed. For example, if the size of the noise code is fixed to 1 byte and the payload length of the short packet is 1 byte, it is determined that the noise code is not multiplexed, and if it is 2 bytes, it is determined that two noise codes are multiplexed. You may make it do.

  In the first embodiment of the present invention, the noise code is multiplexed by the noise code multiplexing unit 106, but the number of noise codes transmitted in one short packet is limited to one, and the second and subsequent noises to be multiplexed. The code may not be sent. For example, when creating a new short packet, the noise code is stored as the payload of the short packet, and when the noise code is multiplexed, the noise code is not added to the payload of the short packet, and the encoding type of the short packet header Only the contents of may be updated. Thereby, the effect that the transmission efficiency in a silence area improves further is acquired.

  Further, according to the first embodiment of the present invention, the multiplexed packet assembling unit 107 has the total length of the short packets stored in the short packet storage buffer 104 and the short packets stored in the noise code multiplexing unit 106. Is set as a condition for multiplexing, a timer for measuring the short packet accumulation time in the short packet accumulation buffer 104 and the noise code multiplexing unit 106 is prepared, and the short packet accumulation time is set in advance. When the threshold value is exceeded, short packet multiplexing may be performed. As a result, it is possible to suppress the short packet transmission delay.

  Further, according to the first embodiment of the present invention, the voice / silence determination unit 102 determines that the received voice data of the IP packet is ITU-T recommendation G.264. Although it is determined that silence compression is possible only when encoding is performed according to the H.711 compliant 64 kbit / s PCM system, it may be determined that silence compression is possible even when encoded using another system.

Embodiment 2. FIG.
In the first embodiment, the noise code is multiplexed and transmitted instead of the voice data determined to be silent. However, in the second embodiment, only the header information of the short packet is transmitted when the voice data is silent. To do.

  FIG. 4 is a block diagram showing a configuration of a packet multiplex transmission apparatus according to Embodiment 2 of the present invention. In this figure, an IP packet receiving unit 101, a voice / silence determining unit 102, a short packet assembling unit 103, a short packet storing buffer 104, a multiplexed packet assembling unit 107, a multiplexed packet transmitting unit 108, and a multiplexed packet receiving unit 109. Since the multiplexed packet decomposing unit 110, the IP packet assembling unit 114, and the IP packet transmitting unit 115 are the same as those in the first embodiment, the description thereof is omitted.

  201 creates a short packet header from the IP packet of the voice data determined to be silent by the voice / silence determination unit 102, and the IP packet of the same voice channel including the voice data determined to be silent as one short packet header A silence packet multiplexing unit 202 that multiplexes the packets, a silence compression determination unit 202 that determines whether or not the short packet decomposed by the multiplexed packet decomposition unit 110 is silence-compressed, and a silence compression determination unit 203 that is silence-compressed by the silence compression determination unit 202 This is a silent packet separator that extracts information on multiplexed short packets from the short packet header determined to be present.

Next, the operation will be described.
First, the operation when the packet multiplex transmission apparatus receives an IP packet from a VoIP terminal will be described. Since the operation when the voice data of the input IP packet is determined to be sound by the sound / silence determination unit 102 is the same as that of the first embodiment, the description thereof is omitted.

  When the voice data of the input IP packet is determined to be silent by the voice / silence determination unit 102, the voice / silence determination unit 102 outputs the input IP packet to the voice packet multiplexing unit 201. Then, the silent packet multiplexing unit 201 identifies a voice channel from the input IP packet and determines whether or not a short packet of the same voice channel has already been accumulated. If no short packet of the same voice channel is accumulated, a short packet is newly created from the input IP packet. For example, only necessary information is extracted from the IP / UDP / RTP header of the input IP packet to create the header information of the short packet shown in FIG. At this time, code information corresponding to previously defined silent audio data is stored in the encoding type of the short packet header. The silent packet multiplexing unit 201 stores nothing in the payload of the short packet.

  If short packets of the same voice channel have already been accumulated, the coding type code information included in the short packet header that has already been accumulated is updated according to the number of multiplexed silent voice data. For example, encoding type code information is defined in a form corresponding to the number of multiplexing of silent audio data, and the corresponding code information is searched every time silent audio data is multiplexed, and the encoding type area is searched. To store. And nothing is added to the payload of the short packet.

  Next, the multiplexed packet assembling unit 107 calculates the total length of the short packets stored in the short packet storage buffer 104 and the short packets stored in the silent packet multiplexing unit 201, and the calculated total length is calculated in advance. When the set threshold value is exceeded, the short packet stored in the short packet storage buffer 104 and the short packet stored in the silent packet multiplexing unit 201 are multiplexed to create a multiplexed packet. Then, the multiplexed packet assembling unit 107 outputs the created multiplexed packet to the multiplexed packet transmitting unit 108, and the multiplexed packet transmitting unit 108 transmits the multiplexed packet to the counterpart packet multiplexing transmission device.

Next, the operation when a multiplexed packet is received from the counterpart packet multiplexing transmission apparatus will be described. Note that the operations of multiplexed packet receiving section 109 and multiplexed packet decomposing section 110 are the same as those in the first embodiment, and a description thereof will be omitted.
The silence compression determining unit 202 refers to the header information of the short packet input from the multiplexed packet decomposing unit 110, checks the code information stored in the encoding type area, and the voice data in which the short packet is silent It is determined whether or not. When it is determined that the input short packet is not silent audio data, the input short packet is output to the IP packet assembling unit 114. Then, the IP packet assembly unit 114 creates an IP packet from the header information of the short packet input from the silence compression determination unit 202. For example, an IP / UDP / RTP header is generated from the header information of the short packet, and the payload of the short packet is stored in the payload of the RTP packet.

On the other hand, when the silence compression determination unit 202 determines that the short packet is silence audio data, the silence compression determination unit 202 outputs the input short packet to the silence packet separation unit 203. Then, the silent packet separation unit 203 refers to the encoding type from the header information of the input short packet, and determines whether or not the silent voice data is multiplexed. For example, an encoding type code is defined in a form corresponding to the multiplexing number of silent audio data, and the multiplexing number can be acquired from the encoding type value. When the silence voice data is not multiplexed, the silence packet separation unit 203 outputs the prepared silence output voice data and the short packet header to the IP packet assembly unit 114. In addition, when the silent voice data is multiplexed, the voice data for silent output prepared in advance and the input short packet header are output to the IP packet assembling unit 114. Next, the same audio data for silent output and a short packet header obtained by adding 1 to the serial number are output to the IP packet assembling unit 114. Thereafter, each time one piece of audio data for silent output is output, the serial number included in the short packet header is incremented by 1 and output to the IP packet assembling unit 114.
The operations of IP packet assembling unit 114 and IP packet transmitting unit 115 are the same as those in the first embodiment, and a description thereof will be omitted.

  As described above, according to the second embodiment of the present invention, when there are a plurality of voice data determined to be silent in the same voice channel, and these voice data are multiplexed into the same IP packet, Since the silence packet multiplexing unit 201 assembles the voice data as one short packet, when transmitting a packet of voice data determined to be silent, it is possible to reduce an increase in overhead of header information. The effect that the transmission efficiency in a section improves is acquired.

  In Embodiment 2 of the present invention, since all IP packets received from the VoIP terminal are transmitted as short packets, the counterpart packet multiplexing transmission apparatus transmits the IP packet to the VoIP terminal at an appropriate timing. Is possible.

  Further, in Embodiment 2 of the present invention, when an IP packet including voice data determined to be silent is converted into a short packet, only the short packet header is transmitted, so that transmission efficiency in the silent period is improved. An effect is obtained.

  Further, according to the second embodiment of the present invention, the multiplexed packet assembling unit 107 has the total length of the short packet stored in the short packet storage buffer 104 and the short packet stored in the silent packet multiplexing unit 201. Is set as a condition for multiplexing, a timer for measuring the short packet accumulation time in the short packet accumulation buffer 104 and the silent packet multiplexing unit 201 is prepared, and the short packet accumulation time is set in advance. When the threshold value is exceeded, multiplexing of short packets may be performed. Thereby, the effect that transmission delay of a short packet can be suppressed is obtained.

Embodiment 3 FIG.
In the first embodiment and the second embodiment, a method for converting an IP packet including voice data determined to be silent into a short packet is fixed. The method of converting into short packets is changed.

  FIG. 5 is a block diagram showing a configuration of a packet multiplex transmission apparatus according to Embodiment 3 of the present invention. In this figure, an IP packet receiving unit 101, a voice / silence determination unit 102, a short packet assembly unit 103, a short packet storage buffer 104, a noise code generation unit 105, a multiplexed packet assembly unit 107, a multiplexed packet decomposition unit 110, Since the noise signal generation unit 113, the IP packet assembly unit 114, and the IP packet transmission unit 115 are the same as those in the first embodiment, description thereof is omitted.

  301 creates a short packet from the noise code generated by the noise code generation unit 105 and the IP header of the voice data converted into the noise code, and when the load on the transmission path is low, the noise code of the same voice channel is short-circuited. When the load on the transmission path is high, the noise code / silent packet multiplexing unit 302 stores only the multiplexed information in one short packet header, and the multiplexed packet generated by the multiplexed packet assembling unit 107 is stored. It is a multiplexed packet transmission unit that outputs the amount of data transmitted to the destination packet multiplexing transmission apparatus.

  Reference numeral 303 denotes a multiplexed packet receiver that receives a multiplexed packet transmitted from the packet multiplex transmission apparatus at the other end, and outputs the amount of received data. 304 is a silence compression of the short packet decomposed by the multiplexed packet decomposer 110. A silence compression determination unit 305 for determining whether or not a short packet that has been determined to be silently compressed by the silence compression determination unit 304 includes a noise code, and includes a noise code. A noise code / silence packet separation unit that separates the multiplexed noise code into individual noise codes, and 306 indicates a transmission data amount from the multiplexed packet transmission unit 302 and a reception from the multiplexed packet reception unit 303. Calculate the load on the transmission line from the amount of data, and determine that the load on the transmission line is high. A transmission line load control unit for outputting a suppressing signal transmission of noise code to the multiplexing unit 301.

Next, the operation will be described.
First, the operation when the packet multiplex transmission apparatus receives an IP packet from a VoIP terminal will be described. The operation when the transmission line load control unit 306 does not output a signal for suppressing the transmission of the noise code to the noise code / silent packet multiplexing unit 301 is performed except for the multiplexed packet transmission unit 302. Since it is the same as Form 1, description is abbreviate | omitted. In this case, the noise code / silent packet multiplexing unit 301 operates in the same manner as the noise code multiplexing unit 106. The operation when the transmission path load control unit 306 outputs a signal for suppressing the transmission of the noise code to the noise code / silent packet multiplexing unit 301 is performed except for the multiplexed packet transmission unit 302. Since it is the same as that of form 2, description is abbreviate | omitted. In this case, the noise code / silent packet multiplexing unit 301 performs the same operation as the silent packet multiplexing unit 201.
The multiplexed packet transmitting unit 302 transmits the multiplexed packet created by the multiplexed packet assembling unit 107 to the counterpart packet multiplexing transmission device, and outputs the transmitted data amount to the transmission line load control unit 306.

Next, the operation when a multiplexed packet is received from the counterpart packet multiplexing transmission apparatus will be described. In this case, the packet multiplexing transmission apparatus receives the multiplexed packet transmitted from the counterpart packet multiplexing transmission apparatus by the multiplexed packet receiving unit 303 and outputs the received packet to the multiplexed packet decomposing unit 110. Multiplex packet receiving section 303 outputs the data amount of the received IP packet to transmission path load control section 306. Next, the multiplexed packet decomposing unit 110 decomposes the multiplexed packet input from the multiplexed packet receiving unit 303 into individual short packets and outputs the short packets to the silence compression determination unit 304 for each short packet.
The silence compression determination unit 304 checks the code information stored in the encoding type of the header information of the short packet input from the multiplexed packet decomposition unit 110, and determines whether or not the sound data is determined to be silence. Determine. If it is determined that the input short packet is not voice data determined to be silent, the input short packet is output to the IP packet assembling unit 114.

  On the other hand, when the silence compression determination unit 304 determines that the short packet is silence audio data, the silence compression determination unit 304 outputs the input short packet to the noise code / silence packet separation unit 305. Then, the noise code / silent packet separation unit 305 refers to the encoding type included in the header information of the input short packet, and determines whether or not the noise code is included in the short packet. For example, the multiplexing number when storing the noise code and the multiplexing number when not storing the noise code are defined as code information of different encoding types, and the presence / absence of the noise code and the multiplexing number are determined from the encoding type value. Make it available.

  If the noise code is included in the short packet and the noise code is not multiplexed, the noise code / silent packet separation unit 305 outputs the noise code of the short packet to the noise signal generation unit 113, and the short packet header Is output to the IP packet assembling unit 114. If the noise code is multiplexed, the noise code at the head of the short packet is output to the noise signal generation unit 113 and the short packet header is output to the IP packet assembly unit 114. Next, the second stored noise code is output to the noise signal generation unit 113, the serial number included in the short packet header is incremented by 1, and then the short packet header is output to the IP packet assembly unit 114. Thereafter, each time one noise code is output, the serial number included in the short packet header is incremented by one and output.

  If the short packet does not include a noise code and the audio data is not multiplexed, the noise code / silent packet separation unit 305 outputs a noise code prepared in advance to the noise signal generation unit 113 to perform a short circuit. The packet header is output to the IP packet assembly unit 114. If the audio data is multiplexed, the prepared noise code is output to the noise signal generation unit 113 and the input short packet header is output to the IP packet assembly unit 114. Next, the same noise code is output again to the noise signal generation unit 113, the serial number included in the short packet header is incremented by 1, and then the short packet header is output to the IP packet assembly unit 114. Thereafter, each time one noise code is output, the serial number included in the short packet header is incremented by one and output.

Next, the operation of the transmission line load control unit 306 will be described. The transmission line load control unit 306 monitors the transmission data amount input from the multiplexed packet transmission unit 302 and the reception data amount input from the multiplexed packet reception unit 303, and the sum of the transmission data amount and the reception data amount is determined in advance. When the threshold value is exceeded, a signal for suppressing transmission of the noise code is output to the noise code / silent packet multiplexing unit 301. Then, when the sum of the transmission data amount and the reception data amount becomes less than a predetermined threshold value, output of a signal for suppressing transmission of the noise code to the noise code / silent packet multiplexing unit 301 is stopped. .
The operations of IP packet assembling unit 114 and IP packet transmitting unit 115 are the same as those in the first embodiment, and a description thereof will be omitted.

  As described above, according to the third embodiment of the present invention, when there are a plurality of noise codes of the same voice channel and these noise codes are multiplexed into the same IP packet, the noise code / silent packet When the multiplexing unit 301 assembles these noise codes as one short packet and transmits a packet of audio data determined to be silent, an increase in header information overhead can be reduced. The transmission efficiency is improved.

Further, according to the third embodiment of the present invention, when there are a plurality of audio data determined to be silent on the same audio channel and these audio data are multiplexed into the same IP packet, the noise code / Since the silent packet multiplexing unit 301 assembles the voice data as one short packet header, when transmitting a packet of voice data determined to be silent, an increase in overhead of header information can be reduced. The effect that the transmission efficiency in a silence area improves is acquired.

  In Embodiment 3 of the present invention, since all IP packets received from the VoIP terminal are transmitted as short packets, the destination packet multiplex transmission apparatus transmits the IP packet to the VoIP terminal at an appropriate timing. Is possible.

  Further, in the third embodiment of the present invention, the transmission path load control unit 306 switches the method of converting the voice data determined to be silent into a short packet according to the transmission path load, so that congestion of the transmission path can be suppressed. The effect is obtained.

  In the third embodiment of the present invention, the information regarding the multiplexing of the noise code is stored as the code information of the encoding type of the short packet header, but the payload length is stored in the short packet header, and the payload length This information may indicate that the noise code is multiplexed. For example, if the size of the noise code is fixed to 1 byte and the payload length of the short packet is 1 byte, it is determined that the noise code is not multiplexed, and if it is 2 bytes, it is determined that two noise codes are multiplexed. You may make it do.

  In Embodiment 3 of the present invention, the noise code is multiplexed by the noise code / silence packet multiplexing unit 301. When the transmission line load control unit 306 determines that the load on the transmission line has increased, The noise code transmitted in one short packet may be limited to one, and the second and subsequent noise codes to be multiplexed may not be transmitted. For example, when creating a new short packet, the noise code is stored as the payload of the short packet, and when the noise code is multiplexed, the noise code is not added to the payload of the short packet, and the encoding type of the short packet header Only the contents of may be updated. As a result, it is possible to select an appropriate transmission method according to the load on the transmission path.

  Further, according to the third embodiment of the present invention, the multiplexed packet assembling unit 107 has the short packet stored in the short packet storage buffer 104 and the short packet stored in the noise code / silent packet multiplexing unit 301. As a multiplexing condition, a timer for measuring the short packet accumulation time in the short packet accumulation buffer 104 and the noise code / silent packet multiplexing unit 301 is prepared, and short packets are accumulated. When the time exceeds a preset threshold value, multiplexing of short packets may be performed. As a result, it is possible to suppress the short packet transmission delay.

  By applying the packet multiplex transmission apparatus of the present invention to a DCME (Digital Circuit Multiplexing Equipment) that packetizes and transmits voice signals of VoIP equipment and the like, DCME reduces the number of packets and transmits them. Efficiency can be improved.

It is a block diagram which shows the structure of the packet multiplexing transmission apparatus by Embodiment 1 of this invention. It is a format figure of the header information of a short packet. It is a format figure of the multiplexed short packet. It is a block diagram which shows the structure of the packet multiplexing transmission apparatus by Embodiment 2 of this invention. It is a block diagram which shows the structure of the packet multiplexing transmission apparatus by Embodiment 3 of this invention.

Explanation of symbols

  101; IP packet receiving unit; 102; voice / silence determination unit; 103; short packet assembly unit; 104; short packet storage buffer; 105; noise code generation unit; 106; noise code multiplexing unit; 108; multiplexed packet transmitting unit 109; multiplexed packet receiving unit 110; multiplexed packet decomposing unit 111; silence compression determining unit 112; noise code separating unit 113; noise signal generating unit 114; IP Packet assembly unit 115; IP packet transmission unit 201; Silence packet multiplexing unit 202; Silence compression determination unit 203; Silence packet separation unit 301; Noise code / silence packet multiplexing unit 302; Multiplexed packet transmission unit 303; Multiplexed packet receiving unit; 304; Silence compression determination unit; 305; Noise code / silence Packet separating unit, 306; transmission line load control unit.

Claims (7)

Voice / silence determination means for determining voice / silence of voice data included in the packet received from the terminal device;
Short packet assembling means for assembling a short packet from information of packets determined to be sound by the sound / silence determining means;
Short packet storage means for storing short packets assembled by the short packet assembly means;
Short packet multiplexing means for assembling and multiplexing short packets from information of packets determined to be silent by voice / silence determination means;
Multiplex packet assembling means for multiplexing short packets stored in short packet storage means and short packet multiplexing means,
Multiplexed packet transmitting means for transmitting the packet assembled by the multiplexed packet assembling means to the packet multiplex transmission apparatus at the other end,
Multiplexed packet decomposing means for decomposing a packet from a packet multiplex transmission apparatus at the other end and taking out a short packet that is multiplexed
Silence compression determination means for determining whether or not the short packet taken out by the multiplexed packet decomposition means is silently compressed,
Short packet separation means for decomposing a short packet determined to be silently compressed by the silence compression determination means and extracting information of the multiplexed short packets;
A packet assembling means for assembling a packet to be transmitted to the terminal device using the information of the short packet;
A packet multiplex transmission apparatus comprising packet transmission means for transmitting a packet assembled by the packet assembling means to a terminal device. Noise code generation means for generating a noise code from voice data included in a packet determined to be silent by the voice / silence determination means;
A noise signal generating means for generating audio data from the noise code;
The short packet multiplexing means assembles a short packet and multiplexes the noise code from the information of the noise code generated by the packet determined to be silent by the voice / silence determination means and the noise code generation means,
The short packet separating unit extracts a noise code multiplexed by decomposing the short packet determined to be silence-compressed by the silence compression determining unit, and outputs the extracted noise code to the noise signal generating unit. The packet multiplex transmission apparatus according to claim 1. The short packet multiplexing means assembles a short packet and multiplexes a short packet header from information of a packet determined to be silent by the voice / silence determination means,
2. The packet multiplexing according to claim 1, wherein said short packet separating means extracts the short packet header multiplexed by decomposing the short packet determined to be silence-compressed by said silence compression determining means. Transmission equipment. Noise code generation means for generating a noise code from voice data included in a packet determined to be silent by the voice / silence determination means;
Noise signal generating means for generating audio data from the noise code;
Transmission path load that determines the load on the transmission path and instructs the short packet multiplexing means to stop multiplexing the noise code and multiplex the short packet header when it is determined that the transmission path is high With control means,
In response to an instruction from the transmission path load control means, the short packet multiplexing means assembles a short packet from the information of the noise code generated by the packet determined by the voice / silence determination means and the noise code generation means, Multiplex noise code or short packet header,
The short packet separating means disassembles the short packet determined to be silence-compressed by the silence compression determining means, and when the noise code is multiplexed, takes out the noise code and outputs it to the noise signal generating means. 2. The packet multiplex transmission apparatus according to claim 1, wherein when the short packet header is multiplexed, the short packet header is taken out.   5. The packet multiplex transmission apparatus according to claim 1, wherein the voice / silence determination means performs voice / silence determination only for a specific encoding method.   The multiplexed packet assembly means calculates the total length of the short packets stored in the short packet storage means, and multiplexes the short packets when the total length of the short packets exceeds a predetermined threshold. The packet multiplex transmission apparatus according to claim 1, wherein the packet multiplex transmission apparatus is performed.   The multiplexed packet assembling means includes a timer for measuring a time during which the short packet is accumulated in the short packet accumulating means, and short-circuits when the short packet accumulation time exceeds a predetermined threshold. The packet multiplexing transmission apparatus according to claim 1, wherein the packet multiplexing is performed.

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