JP4515979B2 - IP phone - Google Patents

Description

  The present invention relates to an IP telephone, and more particularly, to an IP telephone having a function of suppressing voice interruption at the start of a call.

In recent years, with the spread of broadband communication networks, IP telephones that perform voice communication using an IP (Internet Protocol) network are rapidly spreading. The IP network is a communication network such as the Internet or a LAN (Local Area Network) that uses IP as a communication protocol. A technique for realizing voice communication via an IP network is called VoIP (Voice over IP). In VoIP, voice communication is realized by transmitting voice data in the form of RTP (Real Time Protocol) packets between IP telephones. That is, the arrival interval of RTP packets that arrive via the IP network is often irregular. In RTP communication, the arrival time of an RTP packet may vary (jitter) due to communication traffic of an IP network that dynamically changes. In order to continuously output the decoded voice in the IP telephone on the packet receiving side, it is necessary to input RTP packets to the decoder at regular intervals. Patent Document 1 proposes a speech decoding apparatus that absorbs jitter by providing a jitter buffer in front of the decoder.
Japanese Patent Application Laid-Open No. 2004-282692

  However, in the IP telephone, various types of information necessary for call connection control and the like are exchanged with the call connection server and the call connection gateway before the call is started. Currently, it takes about 200 ms to exchange such information. In the future, in order to enhance security, when the exchange of keys is included in the call connection control of the IP telephone, it is expected that the time until the call session is established will be further increased. If the talker begins to speak while the call session is not established, the sent voice may be interrupted.

  An object of the present invention is to solve such a problem and to provide an IP telephone that suppresses transmission voice interruption immediately after the start of a call.

  In order to solve the above problems, an IP telephone according to the present invention includes a buffer memory that first-in first-out RTP packets including transmitted voice or received voice, and a processor that controls transmission / reception of RTP packets to / from an IP network. The processor writes the RTP packet including the transmission voice into the buffer memory in a period until the call session is established, and includes the RTP including the transmission voice in a period until a predetermined time elapses after the call session is established. The packet is written in the buffer memory, and the RTP packets written in the buffer memory are read out in order from the oldest and sent to the IP network. After a predetermined time has elapsed since the call session was established, the buffer memory Is controlled as a jitter buffer that absorbs jitter of RTP packets including

  The processor controls the buffer memory as a jitter buffer after all RTP packets written in the buffer memory are read out and transmitted to the IP network in a period from when the call session is established until a predetermined time elapses.

  The processor controls the time interval for reading the RTP packet written in the buffer memory during a period from when the call session is established until the predetermined time elapses to be shorter than the time interval for writing to the buffer memory. . Thereby, the RTP packet stored in the buffer memory in the initial stage of the call can be emptied, and thereafter, the buffer memory can be used as a jitter buffer.

  According to the present invention, a buffer memory used as a jitter buffer is used as a transmission delay memory at the initial stage of a call, and a transmission voice produced by a caller while a call session is not established is buffered as an RTP packet. It is possible to suppress the voice break at the start of the call by writing in the.

  FIG. 1 shows the system configuration of an IP telephone 10 according to the present embodiment. The IP telephone 10 mainly includes a microphone 11, an encoder 12, an RTP packet processing unit 13, an MPU (processor) 14, a buffer memory (jitter buffer) 15, a decoder 16, and a speaker 17. The transmitted voice input from the microphone 11 is A / D converted and encoded by the encoder 12, and then RTP packetized by the RTP packet processing unit 13. The RTP packet 60 is sent to the IP network 30 under the control of the MPU 14. On the other hand, when the MPU 14 receives the RTP packet 60 from the IP network 30, the MPU 14 sequentially writes the RTP packet 60 in the buffer memory 15. As the buffer memory 15, for example, a FIFO (First In First Out) memory such as a ring buffer memory is suitable. The MPU 14 sequentially reads the RTP packets 60 written in the buffer memory 15 by a first-in first-out method, and transfers them to the decoder 16. The RTP packet 60 transferred to the decoder 16 is decoded and D / A converted, and output from the speaker 17 as a received voice.

  FIG. 2 shows a network configuration of the IP telephone system. As shown in the figure, IP telephones 10 and 20, a call connection server 40, and a call connection gateway 50 are connected to the IP network 30 to construct an IP telephone system. IP telephones 10 and 20 are assigned terminal numbers A1 and B1, respectively. The call connection gateway 50 is given terminal numbers A2 and B2 corresponding to the representative numbers of the terminal numbers A1 and B1, and IP addresses A2-IP and B2-IP corresponding to these terminal numbers. When a call to numbers A2 and B2 is detected, this is a network server having a function of making a call connection between a calling terminal and a called terminal. The call connection server 40 is a network server having a function of making a call connection by associating a terminal number with an IP address. The terminal number A1, B1, A2, B2 and the IP address A1- corresponding to these terminal numbers. IP, B1-IP, A2-IP, and B2-IP are stored in association with each other.

  FIG. 3 shows a processing sequence in which the IP telephone 10 (hereinafter referred to as IP telephone A) calls the IP telephone 20 (hereinafter referred to as IP telephone B) via the call connection gateway 50. When IP telephone A makes a call to the representative number (terminal number B2) of IP telephone B in order to make a call connection to IP telephone B (S101), call connection server 40 registers IP telephone A in advance in call connection server 40. It is confirmed whether or not the terminal is a connected terminal (S102). If IP telephone A is a previously registered terminal, call connection server 40 returns IP address B2-IP corresponding to terminal number B2 (S103). Then, IP phone A makes a call connection request to IP address B2-IP (S104). Since the IP address B2-IP is given to the call connection gateway 50, the call of the IP telephone set A is connected to the call connection gateway 50.

  When the call connection gateway 50 detects a call from the IP telephone A to the IP address B2-IP, the call connection gateway 50 checks whether or not the connection permission for the IP telephone A to make a call connection to the IP telephone B is given (S105). When the connection permission is set, the call connection gateway 50 makes a call connection request to the IP address B1-IP (S106). When IP telephone B responds to this call connection request (S107), call connection is established between call connection gateway 50 and IP telephone B (S108). When the call connection gateway 50 receiving the response from the IP telephone B returns a response signal to the IP telephone A (S109), a call connection is established between the call connection gateway 50 and the IP telephone A (S110). As a result, IP phone A and IP phone B are call-connected via call connection gateway 50 (S111). Thus, in order for IP telephone set A to make a call connection to IP telephone set B, call connection control of call connection server 40, call connection gateway 50, etc. is required. Cost.

  In the present embodiment, the buffer memory 15 used as a jitter buffer is used as a transmission delay memory at the initial stage of a call start, and is transmitted until a predetermined time elapses after a call session is established. The RTP packet 60 in which the speech voice is encoded is written in the buffer memory 15. Then, at the stage when the call session is established, the MPU 14 reads the RTP packet 60 written in the buffer memory 15 by the first-in first-out method at an interval shorter than the transmission interval of the RTP packet 60, and reads the read RTP packet 60 in the IP network. 30. As a result, even if the sender starts a call while the call session is not established, the call can be made without interruption of the call voice. After a predetermined time (at least the time until the RTP packet written in the buffer memory 15 becomes empty) elapses after the call session is established, the buffer memory 15 is a jitter buffer that absorbs jitter of the received voice. used.

  FIG. 4 shows the flow of RTP packets at the start of a call. In the following description, the IP telephone 10 is the calling terminal, the IP telephone 20 is the called terminal, the time until the call session is established is 200 ms, the transmission interval of the RTP packet 60 is 20 ms, and can be stored in the buffer memory 15. The maximum accommodation number of RTP packets is 10 packets.

  FIG. 2A shows a state immediately after the IP telephone 10 makes a call. Since the call session has not been established yet, the RTP packets P1, P2, P3 and P4 including the transmitted voice are sequentially written in the buffer memory 15.

  FIG. 5B shows a state immediately before a call session is established. The buffer memory 15 stores 10 RTP packets 60.

  FIG. 3C shows a state immediately after the call session is established. The RTP packets P1, P2,..., P10 written in the buffer memory 15 are read out by the first-in first-out method at intervals of 10 ms and sent to the IP network 30. At the same time, RTP packets P11, P12, P13, and P14 encoded at intervals of 20 ms are written into the buffer memory 15.

  FIG. 4D shows an excessive state from the establishment of the call session to the transition to the steady state. RTP packets are written into the buffer memory 15 at intervals of 20 ms, while old RTP packets are sequentially read out at intervals of 10 ms and sent to the IP network 30. In the buffer memory 15, RTP packets that have not yet been read are accumulated in a first-order manner, and a newly written RTP packet is added at the end. Since the time interval of RTP packets read from the buffer memory 15 is shorter than the time interval of RTP packets written to the buffer memory 15, the number of RTP packets stored in the buffer memory 15 gradually decreases.

  On the other hand, the IP telephone 20 absorbs the jitter of the arrival packet by writing the RTP packet received from the IP network 30 into the buffer memory (jitter buffer) 25. Then, RTP packets are read from the buffer memory 25 at intervals of 20 ms, transferred to the decoder 22 and decoded.

  FIG. 5E shows a state (steady state) in which 400 ms or more has elapsed since the establishment of the call session. When 400 ms elapses after the call session is established, all 20 RTP packets including the transmitted voice are sent to the IP network 30, and the buffer memory 15 becomes empty. In the steady state, the RTP packet sent from the IP telephone 10 is sent directly to the IP network 30 without being written to the buffer memory 15. In the steady state, it is not necessary to use the buffer memory 15 as a transmission delay memory, so that the buffer memory 15 is used as a jitter buffer that absorbs the jitter of the RTP packet transmitted from the IP telephone set 20.

  As described above, until a predetermined time (for example, 400 ms) elapses after the call session is established, the MPU 14 uses the buffer memory 15 as a transmission delay memory, and transmits RTP packets that carry transmission voice to the buffer memory 15. First-in first-out and sent to the IP network 30. As a result, it is possible to make a call without interrupting the transmitted voice at the start of the call. After a predetermined time (for example, 400 ms) has elapsed since the call session was established, the MPU 14 switches the input / output path of the RTP packet to the buffer memory 15 and uses the buffer memory 15 as a jitter buffer.

1 is a system configuration diagram of an IP telephone according to an embodiment. It is a network block diagram of an IP telephone system. It is a call connection sequence in an IP telephone system. It is explanatory drawing which shows the flow of the RTP packet at the time of a telephone call start.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... IP telephone 11 ... Microphone 12 ... Encoder 13 ... RTP packet processing part 14 ... MPU 15 ... Buffer memory 16 ... Decoder 17 ... Speaker 20 ... IP telephone 22 ... Decoder 25 ... Buffer memory 30 ... IP network 40 ... Call Connection server 50 ... Call connection gateway 60 ... RTP packet

Claims (3)

A buffer memory for first-in first-out RTP packets including transmitted voice or received voice;
A processor for controlling transmission / reception of the RTP packet to / from an IP network,
The processor writes an RTP packet including a transmission voice to the buffer memory in a period until a call session is established, and transmits a transmission voice in a period until a predetermined time elapses after the call session is established. The RTP packet that is included is written to the buffer memory, and the RTP packets written to the buffer memory are read out in order from the oldest and sent to the IP network. After a predetermined time has elapsed since the establishment of the call session, An IP telephone that controls a buffer memory as a jitter buffer that absorbs jitter of RTP packets including received voice.   2. The IP telephone according to claim 1, wherein the processor reads all RTP packets written in the buffer memory during a period from when a call session is established until a predetermined time elapses, to the IP network. An IP telephone that controls the buffer memory as a jitter buffer after being sent to   3. The IP telephone according to claim 1, wherein the processor sets a time interval for reading an RTP packet written in the buffer memory in a period from when a call session is established until a predetermined time elapses. The IP telephone is controlled so as to have a time interval shorter than a time interval for writing to the buffer memory.

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