JPH01296739A - Voice packet transmission control system - Google Patents

Abstract

PURPOSE:To attain the delay control of a voice packet with high accuracy by processing the head packet of a series of voice packet groups or the control packet ahead the voice packet group with priority and retarding the packet from the arrival time of the packet. CONSTITUTION:In the case of a control packet, control information is given to an information field 16, in the case of a voice packet, a frame number 16-1 and a voice data 16-2 are given and in the case of a data packet, a sequence number 16-3 and a data 16-4 are given to the information field 16. Other code is assigned to a packet type 15 of the voice packet so as to identify the head packet and other packets. The minimum transmission delay time acquisition packet ahead the head voice packet or the voice packet is processed with priority over other voice packet, then the transmission delay time of the packet is minimized. In the case of application of control based on the packet reception time in this way, the delay control of the voice packet with high accuracy is attained.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a method for transmitting and reproducing audio in the form of packets. In particular, in order to prevent deterioration in speech quality, the delay time of packets is adjusted on the receiving side. The present invention relates to a method for correcting fluctuations in data and discarding packets with large delay times.

[Conventional technology]

In a packet transmission system, the transmission delay time of each packet varies for each packet, so in order to obtain a constant call quality, the transmission delay time of each packet must be corrected on the receiving side so that it is constant. There is a need. Conventional means for correcting transmission delay time are 1, for example, I.E.
IEHE Journal on Selected Areas in Communications
al onSelected Areas in Co
m+l1unications) Volume 5AG-1, Volume 6
issue, pages 1022 to 1028. In method (1) described here, when the first packet is received, it is delayed by the variation width of the transmission delay time, and thereafter the audio frame period (period for one packet of audio data) is set based on this time. delay packets. If no packets arrive within the frame period, the late packets are discarded. Method (2)
Now, the transmission delay time measurement packet is sent back and forth to find the transmission delay time, and this value is transmitted to the receiving side to set the permissible transmission delay time of the packet.

The delay time of subsequent packets is controlled by adding relative time information from this transmission delay time transmission packet. In method (3), the transmitting side adds time data to audio packets and transmits them, and the receiving side calculates the transmission delay time of each received packet from the time data and the time data at the time of reception. This transmission delay time is compared with a predefined allowable transmission delay time.

If the transmission delay time is larger than the allowable transmission delay time, the received packet is discarded, and if it is within the allowable transmission delay time, the packet is delayed by the difference from the allowable transmission delay time. In method (4), the transmission delay time is determined by adding up the processing time in each relay exchange, and the packet is delayed using the obtained transmission delay time in the same manner as in (3). In method (5), the allowable transmission delay time is recalculated based on the number of packets stored in the reception buffer or the transmission delay time obtained by reciprocating the transmission delay time measurement packet as appropriate, and the silent period is used. control the amount of delay by changing the allowable transmission delay time.

[Problem that the invention seeks to solve]

In the conventional method (1), since it is unknown whether the transmission delay time of the first packet is the maximum value or the minimum value, it is considered as the minimum value and the fluctuation range is added to it to determine the allowable transmission delay time. The allowable transmission delay time becomes too large. Method(
Method 2) is a method for improving the accuracy of the allowable transmission delay time of method (1).

Transmission delay time measurement The outbound and return transmission delay times of a packet are not necessarily the same, and the accuracy of the allowable transmission delay time cannot be said to be sufficient. In method (3), it is necessary to match the clocks on the transmitting side and the receiving side for determining the transmission delay time, and therefore it is necessary to distribute the same clock throughout the communication network.

In method (4), the throughput of the relay exchange increases and the transmission delay time increases. Method (5) has high control accuracy, but
This has the disadvantage of requiring a large amount of hardware.

SUMMARY OF THE INVENTION An object of the present invention is to overcome the drawbacks of these conventional techniques and to provide a voice packet transmission control system that is easy to configure a communication network and equipment and is suitable for high-speed packet I/exchange.

[Means for solving problems]

The above purpose is to provide means for processing the first voice packet or the minimum transmission delay time acquisition packet preceding the voice packet with priority over other voice packets in each relay exchange, and on the receiving side, the reception time of this packet is The allowable transmission delay time is determined by either deducting the minimum transmission delay time that can be calculated for this transmission route from the allowable transmission delay time determined by the voice quality as a standard, or by delaying the fluctuation range of the transmission delay time determined by the packet discard rate. year,
Thereafter, this is achieved by extracting the received packets at a constant voice frame period and controlling the transmission delay times to be the same. When determining the transmission route on the transmitting side, is the minimum transmission delay time calculated from the communication network configuration information and transmitted to the receiving side?

The information is transmitted along the transmission path to the receiving side, and the receiving side calculates it from the communication network configuration information.

[Effect]

According to the above method, by processing the first voice packet or the minimum transmission delay time acquisition packet preceding the voice packet with priority over other voice packets, the transmission delay time of this packet can be minimized. If control is performed based on the packet reception time in this way, as in conventional technology, the same clock will be distributed throughout the communication network, and the amount of processing at each relay switch will increase and the hardware size will increase. This makes it possible to control audio packet delay with higher accuracy than before.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of an embodiment of the present invention, where 1 is a telephone and 2 is an encoder that converts an analog audio signal into a digital signal. There may be. 3 is an oscillator, which does not necessarily need to be synchronized with the packet communication system. 4 is a counter for frequency-dividing the output signal of the oscillator 3 and adding a number to the packet every frame period. Reference numeral 5 denotes a section that divides the digital audio data output from the encoder 2 into packet lengths, adds the output of the counter 4 at that time, that is, a frame number, to each audio data, and assembles it into packets.

This part includes a function to treat packets that contain only a signal below a certain level as silent packets and delete them, and a call number or destination address used by the packet switch to switch packets based on the protocol of the packet communication network. 6 is the transmission path, 7 is the transmission path, the received packet is disassembled based on the protocol, and the frame number and audio data are transferred to the next logical block. A portion 8 outputted to the packet disassembly section 7 is a buffer for storing the output of the packet disassembly section 7, and is a first-in first-out buffer. Reference numeral 9 is a part for setting the delay time of the first priority packet, and the setting method will be described later. 10 sets the output of the delay time setting section 9 when receiving the first packet, counts down by the output signal of the oscillator 3, outputs a signal when it reaches O, and thereafter divides the output signal of the oscillator 3. a timer that outputs a signal every frame period, 11;
is a counter that is reset to 0 at the time when the first packet is received, and thereafter updated by 1 based on the output signal of the timer 10. 1
2 is a delay control unit which compares the output of the counter 11 and the frame number of the received packet taken out from the buffer 8, and when they are equal, outputs the audio data of that packet.

When the frame number of the received packet is larger, the extraction of data from buffer 8 is stopped; when the frame number of the received packet is smaller, the audio data of that packet is discarded, and the same process is performed for the next packet stored in buffer 8. Perform processing. 13 is a decoder that converts the digital audio data output from the delay control section 12 into an analog signal. 2, 4, 5, 7, 9 above
The functions of 10.11 and 12.13 can be realized by a dedicated logic circuit, or by a control program for a signal processing processor or a general-purpose microprocessor. In the latter method, a single processor or a plurality of processors are used depending on the processing capacity of the processor.

FIG. 2 shows an example of the format of a packet sent to the transmission line 6. 14 is an address field used by the packet switch to control the next destination of the received packet; 15 is whether the packet is a control packet (a packet for setting the transmission route from the sender to the receiver when a call occurs); Reference numeral 16 is an information field indicating the type of packet, whether it is a voice packet or a data packet (the part that generates the data packet will not be described because it is outside the essence of the present invention). The information field 16 contains control information in the case of a control packet, and frame number 16-1 in the case of an audio packet.
and audio data 16-2. In the case of a data packet, sequence number 16-3 and data 16-4 are carried. Different codes are assigned to the packet types of voice packets so that the first packet and other packets can be distinguished.

The packet switch determines the priority of packet switching processing by looking at the packet type field. That is, when a plurality of packets exist at the same time, processing is performed in the order of control packet, first audio packet, second and subsequent audio packets, and data packet.

As a result, the first voice packet can be processed preferentially except for the control packet, and since the number of control packets is small compared to other packets, the processing time in the packet switch can be brought close to the minimum value, and therefore the minimum transmission delay time can be obtained. I can do it.

FIG. 3 is a time chart showing how audio signals are transmitted by the audio packet transmission control device of FIG. 1, and the operation of this embodiment will be explained based on this. When the sending side picks up the telephone and attempts to call the other party, it finds a packet transmission route based on the destination address, creates a control packet for setting up a call, and sends it to the transmission line 6.

The control information of the control packet includes a source address, a destination address, a transmission route, and a minimum transmission delay time of the transmission route. The control packet is relayed based on the transmission route information, and each relay packet switch stores in its own table information for exchanging the voice packet or data packet transmitted after the control packet to the next switch using the address field 14. Set to . When the control packet arrives at the packet switch on the receiving side, the other party's terminal, in this case a telephone, rings the bell to call the other party. When the other party picks up the telephone, information for outputting the subsequently transmitted voice packet to the other party's telephone is set in the address field 14 in its own table. Further, a delay time td obtained by subtracting the minimum transmission delay time from a predetermined allowable transmission delay time is held in the delay time setting unit 9, and a control packet indicating that call setup has been established is sent to the transmitting side packet switch. The call setup is completed by receiving and accepting this control packet at the transmitting side packet switch.6 or more call setup and packet switching methods themselves may be implemented using other methods, as shown in FIGS. 1 and 3. is not shown.

When the call setup is completed as described above, a conversation can be started through the telephone. 21 to 27 are voice signals from the telephone set 1, indicating that there were valid voice signals during frame periods T1 to T4 and T7Tθ.

TI! This audio signal input, which indicates that there was no valid audio signal between T8 and T8, is encoded into a digital signal by the encoder 2. In the packet assembling section 5, the encoder 2
The digital signal converted by is put into field 16-2 for each frame period, the frame number from counter 4 is put into field 16-1, and packets 31 to 34 are
．． Assemble 37-39. The broken lines 35 and 36 indicate that the packet was not assembled because there was no audio signal in that frame period. Packet 31-34゜3
The frame number fields 16-1 of 7 to 39 are 1, 2, 3, 4, 7, and 8.9, respectively, and are indicated by encircled numbers in the figure. In addition, the packet type field 15 indicates that the packet 31 is the first audio packet, and the other packets 32 to 3 are the first audio packet.
4.37 to 39 indicate audio packets other than the first one. The packets 31 to 34 and 37 to 39 are relayed through the transmission path 6 and the communication network through the address field 14 and reach the receiving side. There is also an audio packet transmission control device shown in FIG. 1 on the receiving side, and 41 to 47 are the received packets. Packet 41, ie, 31, is processed with priority over other packets except for control packets, so it arrives with almost the minimum transmission delay time. The arrival intervals of subsequent packets 42 to 47 differ depending on variations in transmission delay time. The received packets 41 to 47 are decomposed by the packet decomposition unit 7 based on the protocol, and are separated into frame number 16-1 and audio data 16.
-2 is stored in the first-in/first-out buffer 8. On the other hand, when the packet 41 arrives, the delay time td held in the delay time setting section 9 as described above is transferred to the timer 10, and the counter 11 is reset to "0". The timer 10 is counted down by the output signal of the oscillator 3.

When it becomes "0", the counter 11 is updated to "1", and the delay control section 12 takes out the frame number and audio data from the buffer 8. Removed packet 4
The frame number of 1 is 1.

Since it is equal to the content of the counter 11, the audio data 51 is output to the decoder 13. This allows the delay control unit 12 to delay the packet 41 by td, so that the packet 41 arrives at the input of the decoder 13 with a predetermined allowable transmission delay time. Thereafter, the timer 10 outputs a signal every frame period, thereby the counter 11 is updated by 1, and the delay control unit 12 extracts the frame number and audio data from the buffer 8 and inputs the frame number and the counter 11.
Compare the contents of Since they are equal up to packet 44, audio data 52 to 54 are output to the decoder 13 at equal frame periods tf. Therefore, packets 42 to 44 also arrive at the decoder 13 with a predetermined allowable transmission delay time. When the counter 11 reaches r5J and r6J, there is no data in the buffer 8, so the delay control unit 12 does not output audio data. When the counter 11 reaches 7, the packet 45 with the same frame number has arrived, so the audio data 57 is output. Packet 46 occurs when the transmission delay time is greater than the allowable transmission delay time, and has not arrived when the counter 11 reaches 8. Therefore, the delay time control section 12 does not output audio data as in the case of a silent section. In the figure, the audio data that was supposed to be output is indicated by a broken line 56. Next, counter 1
When 1 becomes 9, buffer 8 contains packet 46.
47 data are stored, and first the frame number of packet 46 is taken out and compared with counter 11.

However, since the frame number of the received packet is smaller, the audio data of that packet is discarded and the next packet 47 stored in the buffer 8 is taken out. Since the frame number of packet 47 is equal to counter 11, the audio data 57 is output. As described above, the digital voice data adjusted to a predetermined allowable transmission delay time is converted into an analog signal by the decoder 13, and outputted from the telephone 1 as voices 61 to 66.

In the embodiment shown in FIG. 3, the first packet 31 also includes the audio data 21, but it may also be a dedicated packet for obtaining the minimum transmission delay time.

Further, the minimum transmission delay time may be included as data in this minimum transmission delay time acquisition packet.

In this embodiment, a case is shown in which the allowable transmission delay time is set to a constant value determined from the voice quality, but the allowable transmission delay time can also be determined so that the packet discard rate becomes a constant value.

That is, the allowable transmission delay time is determined by setting the allowable variation width td determined from the packet discard rate in the delay time setting section 9 and delaying the first packet by that amount. The allowable fluctuation range can be changed depending on the number of stages of the repeater exchanger.

The oscillators 3 on the transmitting/receiving and receiving sides do not necessarily need to be synchronized, but the oscillation cycle should be set to such an extent that the cycle on the receiving side is short and the packet discard rate does not become large during the period from the generation of one call until the end of the call. Also, since the cycle on the receiving side is long, it is necessary to have enough accuracy to prevent packets from accumulating in the buffer and overflowing.

〔Effect of the invention〕

According to the present invention, it is possible to achieve higher precision than before without distributing the same clock to the entire communication network, increasing the amount of processing at each relay exchange, or increasing the amount of hardware, as in the prior art. It becomes possible to control the delay of voice packets.

[Brief explanation of the drawing]

FIG. 1 is a schematic configuration diagram of a voice packet transmission control device according to an embodiment of the present invention, FIG. 2 is an example of a packet format, and FIG. 3 is a diagram showing the operation of the voice packet transmission control device of FIG. This is a timing chart. 1... Telephone, 2... Encoder, 3... Oscillator,
4゜11...Counter, 5...Packet assembly section, 6
...Transmission path, 7...Packet decomposition unit, 8...Buffer, 9...Delay time setting unit, 10...Timer, 1
2...Delay control section. 13...Decoder, 14...Address field,
15...Packet type field, 16...Information field, 21-27...Input audio signal, 31-34
゜37-39...Transmission packet, 41-47...Reception packet, 51-55. v1 type P77

Claims (1)

[Claims] 1. Means for identifying that the packet is the first packet of a series of audio packets transmitted over a communication network or a control packet preceding the audio packet group, and means for identifying the packet and for identifying it as a control packet preceding the audio packet group. means for processing with priority over packet processing;
An audio packet transmission control system comprising means for delaying a packet starting from the arrival time of the packet. 2. Starting from the arrival time of the first packet of the voice packet group or the control packet preceding the voice packet group, the time is calculated by subtracting the minimum transmission delay time from the allowable transmission delay time, and from then on, the time at which the voice packet was sent is 2. The audio packet transmission control method according to claim 1, wherein the packet is delayed so as to be approximately equal to the interval. 3. Starting from the arrival time of the first packet of the voice packet group or the control packet preceding the voice packet group, the packet is delayed by the variation width of the transmission delay time, and thereafter the time interval is approximately equal to the time interval at which the voice packets were sent. The voice packet transmission control system according to claim 1, characterized in that packets are delayed.