KR20060011678A - Method and apparatus for classifying and transmitting a realtime transport protocol packet and a realtime transport protocol packet in a mobile communication system - Google Patents

Abstract

The present invention relates to a method and apparatus for a demultiplexer to distinguish between an RTP packet and an RTCP packet on a radio bearer. Since the RTP packet and the RTCP packet have the same IP address but require different quality of service, different radio bearers are used. It is desirable to. The present invention provides a method for distinguishing an RTP packet from an RTCP packet using CID identification information generated in the PDCP layer using a bit value of a PT field or a bit value of the PT field of a packet received by the demultiplexer. In another embodiment of the present invention, the UDP port number to be used for the RTP packet and the RTCP packet is provided to the terminal and the RNC by using the SDP, and the demultiplexer of the terminal and the RNC uses the UDP port number to provide the UDP port number. Identifies RTCP packets.

Therefore, according to the present invention, it is possible to provide a scheme for easily distinguishing between RTP packets and RTCP packets having different characteristics in a UMTS-type mobile communication system for providing VoIP services.

VoIP, RTP, RTCP, Packet, Radio Bearer, Demultiplexer

Description

TECHNICAL AND APPARATUS FOR CLASSIFYING AND TRANSMITTING A REALTIME TRANSPORT PROTOCOL PACKET AND A REALTIME TRANSPORT PROTOCOL PACKET IN A MOBILE COMMUNICATION SYSTEM}             

1 is a block diagram showing a network configuration of a mobile communication system for providing a VoIP service to which the present invention is applied;

2A and 2B illustrate data formats of RTC packets and RTCP packets, respectively.

FIG. 3 is a hierarchical diagram showing an internal hierarchical structure of a UE that distinguishes RTC packets and RTCP packets and transmits them in reverse according to an embodiment of the present invention

FIG. 4 is a hierarchical diagram showing an internal hierarchical structure of a base station and a base station controller for forward transmission by dividing an RTC packet and an RTCP packet according to an embodiment of the present invention.

5 is a flowchart illustrating an operation of a demultiplexer for separately transmitting an RTC packet and an RTCP packet according to an embodiment of the present invention.

6 is a flowchart illustrating a method of distinguishing and transmitting an RTC packet and an RTCP packet according to an embodiment of the present invention.                 

FIG. 7 is a hierarchical diagram illustrating an internal hierarchical structure of a UE that distinguishes RTC packets and RTCP packets and transmits them in reverse according to an embodiment of the present invention

FIG. 8 is a hierarchical diagram illustrating an internal hierarchical structure of a base station Node B and a base station controller RNC for forward transmission by dividing an RTC packet and an RTCP packet according to an embodiment of the present invention.

9 is a flowchart illustrating a method of separately transmitting an RTC packet and an RTCP packet according to an embodiment of the present invention.

The present invention relates to a packet transmission method and apparatus for a mobile communication system for transmitting and receiving a packet through a radio bearer, and in particular, to provide a Voice over Internet Protocol (“VoIP”) service for universal mobile telecommunication systems (UMTS) ) Real-time Transport Protocol (RTP) packet and Real-time Transport Control Protocol (RTCP) packet are distinguished and transmitted to different radio bearers (RB) in the system. It is about the method and the device.

In a general data transmission method, voice service is provided through a circuit switched network such as a public switched telephone network (PSTN), and packet service is a packet service data network (PSDN), which is an IP (Internet Protocol) network. Although it is provided through the IP network, the proposed technology for providing voice service over an IP network is well known VoIP. The VoIP is capable of providing high quality voice calls by overcoming the development of IP networks such as the Internet and the 56kbps voice bandwidth of the circuit network, and providing various application solutions and additional services in addition to being able to use international calls at low costs only using the Internet fee. The number of users is increasing rapidly.

The VoIP service has been provided through the existing wired network, but according to the development of wireless communication technology, the standard group 3GPP and the like are discussing ways to support VoIP communication so that VoIP service can be provided through a mobile terminal. The VoIP refers to a communication technique for transmitting a voice frame generated by a voice coder (codec) into an IP / UDP / RTP packet and transmitting the voice frame. The VoIP may provide a voice service through a packet network.

In the VoIP, voice data is packetized by RTP, which carries a control protocol called RTCP. That is, in a VoIP application, RTP packets and RTCP packets having different characteristics are continuously generated.

First, RTP generates packets of a certain size every relatively short period. The generation period of the RTP packet is determined according to the type of codec. For example, the adaptive multi rate (AMR) codec generates 246 bit speech data every 20 msec. RTCP, on the other hand, generates RTCP packets with relatively long periods and of variable size. For example, according to RTCP, 200 bytes of RTCP packets can be generated in 5 seconds at one moment, and 100 bytes of RTCP packets can be generated in 2.5 seconds at another moment. Another difference is that RTP packets carrying voice data are sensitive to delay and should be transmitted without delay when they occur. However, RTCP packets are relatively insensitive to delay, so they can tolerate a constant buffering delay.

Considering the above difference, it is inefficient to transmit and receive RTP traffic and RTCP traffic through one radio bearer, and it is preferable to transmit and receive through a radio bearer specialized for each traffic. For example, traffic of an RTP packet should be transmitted and received through a radio bearer having a constant transmission rate operating in Radio Link Control (RLC) Unacknowledged Mode (UM), and the traffic of the RTCP packet is retransmitted in an RLC acknowledgment mode ( It operates in Acknowledge Mode (AM) and has to be transmitted / received through a low priority radio bearer with variable transmission rate. In order to transmit and receive the RTP packet and the RTCP packet through different radio bearers as described above, the RTP packet and the RTCP packet must be classified before being input to the corresponding radio bearer.

An object of the present invention is to provide a method and apparatus for distinguishing an RTP packet and an RTCP packet and transmitting them through different radio bearers in a mobile communication system providing a VoIP service.

A method of the present invention for achieving the above object is a method for transmitting a real-time transport packet in a mobile communication system providing a packet data service, the payload type of a real-time transport protocol (RTP) packet from the header information of the input packet Analyzing a field value included in a position corresponding to a field; checking whether the field value is included in a bit value of a specified range; and if the field value is out of the specified range, real-time the input packet. And transmitting the RTCP packet to a first radio bearer layer that processes the packet.

An apparatus of the present invention for achieving the above object is a device for transmitting a real-time transport packet in a mobile communication system providing a packet data service, the payload type field of a real-time transport protocol (RTP) packet from the header information of the input packet A demultiplexer for analyzing a field value included in a position corresponding to and checking whether the field value is included in a bit value of a specified range, and if the field value is out of the specified range, sending the input packet in real time. (RTCP) a first radio bearer layer for delivering a packet to a radio bearer for processing a packet; and a second radio bearer for delivering the input packet to a radio bearer for processing the RTP packet when the field value is included in the designated range. It is characterized by including a layer.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.                     

1 is a block diagram showing a network configuration of a mobile communication system for providing a VoIP service to which the present invention is applied. In recent years, in 3GPP, a multiplexing / demultiplexing apparatus is provided on a radio protocol to distinguish between an RTP packet and an RTCP packet. The transmission method is under consideration.

That is, referring to FIG. 1, a user equipment (UE) 105 multiplexes a predetermined VoIP application 110 generating an RTP packet and an RTCP packet, and demultiplexes and transmits the RTP packet and the RTCP packet to different radio bearers. Firearm / demultiplexer 115 is provided. The RTP packet 130 and the RTCP packet 125 which have passed through the multiplexer / demultiplexer 115 are respectively routed through a base station Node B via a distributed radio bearer. 120). The multiplexer / demultiplexer 135 of the RNC 120 multiplexes the received RTP packet and the RTCP packet to a wired bearer, and the multiplexed RTP packet and the RTCP packet 145 transmitted to the wired bearer are IP networks ( 150 is transmitted to the wired telephone 160 connected to the core network (CN) 140.

On the contrary, the RTP packet and RTCP packet 145 generated and multiplexed in the wired telephone 160 used by the other party's call are transferred to the RNC 120 through the wire bearer, and the multiplexer / demultiplexer of the RNC 120 ( 135 divides the received packet into the RTP packet 130 and the RTCP packet 125, and then demultiplexes the divided packet to the terminal 105 through different radio bearers and transmits the received packet. The multiplexer / demultiplexer 115 of the terminal 105 transmits the received RTP packet 130 and the RTCP packet 125 to the VoIP application 110. The role of the multiplexer / demultiplexer 115, 135 provided in the terminal 105 and the RNC 120, respectively, divides the received IP packet into an RTP packet and an RTCP packet 125 so as to provide an appropriate radio bearer. To pass. Here, the RTP packet 130 and the RTCP packet 125 can be distinguished through a UDP (User Datagram Protocol) port number because the RTP packet and the RTCP packet are assigned UDP port numbers according to the rules 1 and 2 below.

1. An RTP packet has an even UDP port number.

2. The RTCP packet has an odd UDP port number that is one greater than the UDP port number of the RTP packet.

Accordingly, the multiplexer / demultiplexer 115 and 135 of the terminal 105 and the RNC 120 may distinguish between the RTP packet and the RTCP packet only by checking the UDP port number of the received packet even if there is no separate information for packet classification. Can be. However, according to the recently revised RTP standard (RFC 3550), a scheme of freely assigning a UDP port number regardless of the above rules has been introduced. This is because a node such as a network address translator (NAT) may require a specific UDP port number.

Therefore, according to the revised RTP standard, the multiplexer / demultiplexer 115 and 135 of the terminal 105 and the RNC 120 can no longer distinguish between the RTP packet and the RTCP packet by using the UDP port numbers of the received packet. No problem occurs. In order to solve the above problem, the present invention proposes a method of distinguishing an RTP packet from an RTCP packet in a revised RTP standard using a Payload Type (“PT”) field of an RTP packet and a PT field of an RTCP packet. present. In addition, another embodiment of the present invention proposes a method for the UE to inform the RNC of the UDP port number to be used for the RTP packet and the UDP port number to be used for the RTCP packet.

Hereinafter, with reference to FIGS. 2 to 6, a multiplexer / demultiplexer provided in the terminal and the RNC of FIG. 1 distinguishes an RTC packet from an RTCP packet using PT fields of the RTC packet and the RTCP packet. An example will be described.

2A and 2B illustrate data formats of RTC packets and RTCP packets, respectively.

As shown in FIGS. 2A and 2B, the PT (Payload Type) field 210 of the RTP packet and the PT (Packet Type) field 220 of the RTCP packet are located at substantially the same part. To be precise, the PT value of the PT field 210 of the RTP packet corresponds to 7 bits excluding the most significant bit (MSB) from the PT value of the PT field 220 of the RTCP packet. Here, the PT value of the RTP packet represents codec information of the payload of the RTP packet, and the value is predetermined in the call setup process. In addition, 72 to 76 values of PT values of the RTP packet are defined as unused values.

On the other hand, PT value of the RTCP packet indicates the type of the RTCP packet, the value can be used only from 200 to 204. If the MSB 1 bit is excluded from the PT value of the RTCP packet, the value becomes a value between 72 and 76 equal to the PT value of the RTP packet. Therefore, PT values of RTP packets not used from 72 to 76 and PT values of RTCP packets having PT values from 72 to 76 except for the MSB 1 bit do not overlap each other.                     

In addition, considering that the RTP packet and the RTCP packet are transmitted and received through the same lower layer, that is, the IP and UDP layers, the RTP packet and the RTCP packet may be distinguished using PT values having the above characteristics. Accordingly, in the present invention, the packet received by the multiplexer / demultiplexer of the UE and the RNC is regarded as an RTP packet once, and the PT value of the received packet is interpreted, and if the value is between 72 and 76, it is determined as an RTCP packet. If it is anything other than this, it is determined as an RTP packet.

FIG. 3 is a hierarchical diagram illustrating an internal hierarchical structure of a UE that distinguishes RTC packets and RTCP packets and transmits them backwards according to an embodiment of the present invention.

In FIG. 3, VoIP voice data generated by the codec 305 of the terminal is input to the demultiplexer 325 via the RTP layer 310 and the UDP / IP layer 320. During the transmission of the voice data generated by the RTP layer 310, the RTCP layer 315 generates an RTCP packet containing control information and statistical information about the RTP transmission, for example, every 5 seconds and transmits it to the demultiplexer 325. do. The demultiplexer 325 analyzes the PT value of the received packet and if the PT value is a value between 72 and 76, inputs the received packet to the first radio bearer (RB) layer 335 configured for the RTCP packet. If PT is any value other than 72 to 76, the received packet is input to the second RB layer 330 configured for the RTP packet.

Here, the first RB layer 335 configured for the RTCP packet includes a Packet Data Convergence Protocol (PDCP), a Radio Link Control (RLC), etc., which is configured for RTCP packet processing, and includes a second RB layer configured for the RTP packet. 330 is composed of PDCP, RLC, and the like, which are configured for RTP packet processing.                     

Typically, the RB layer is configured per application provided with reference to a Quality of Service (QoS) requirement and is connected to a specific transport channel. The transport channel is a channel located between the MAC 340 layer and the physical (PHY) layer 345 and is defined by a method of processing data on the physical layer. For example, a channel coding scheme, a channel coding rate, a size of a cyclic redundancy code (CRC), and the like may define a transport channel. In other words, the QoS requirements of any application are implemented by the RB layer and the transport channel.

Meanwhile, the RTP packet processed by the second RB layer 330 is delivered to the appropriate transport channel by the MAC layer 340. The physical layer 345 processes the RTP packet in the manner defined in the transport channel and transmits the RTP packet to the wireless channel. In addition, the RTCP packet processed by the first RB layer 335 is delivered to the appropriate transport channel in the MAC layer (340). The physical layer 345 processes the RTCP packet in a manner defined in the transport channel and transmits it to the wireless channel.

Conversely, a packet received over a wireless channel is either a second RB layer 365 configured to process an RTP packet via a physical layer 350 and a MAC layer 355 or a first RB layer 360 configured to process an RTCP packet. Is passed). At this time, the mapping relationship between the transport channel and the RB is used. The packet processed by the first or second RB layers 360 and 365 is delivered to the multiplexer 370, and the multiplexer 370 delivers the delivered packets to the UDP / IP layer 375. Thereafter, the RTP packet is input to the codec 390 through the IP / UDP layer 375 and the RTP layer 385, and the codec 390 converts voice data carried in the RTP packet into real voice. The RTCP packet for control is transmitted to the RTCP layer 380 via the UDP / IP layer 375.

FIG. 4 is a hierarchical diagram illustrating an internal hierarchical structure of a base station Node B and a base station controller RNC for forward transmission by dividing an RTC packet and an RTCP packet according to an embodiment of the present invention.

In FIG. 4, the physical layers 445 and 450 are located at the base station Node B, and the remaining layers are located at the base station controller RNC. First, referring to the operation of each layer of the RNC, the RTP packet and the RTCP packet transmitted from the CN are input to the demultiplexer 425 via the GPRS Tunnelling Protocol (GTP) tunnel layer 420. The GTP tunnel layer 420 configures a wired bearer for transmitting and receiving packet data between the RNC and the CN, and the wired bearer GTP tunnel is identified by a Tunnel Endpoint ID (TEID) added to the GTP header. VoIP packets including RTP packets and RTCP packets are transmitted and received through the GTP tunnel set for each call, and the GTP tunnel layer 420 serves to deliver the VoIP packets to the demultiplexer 425 using the TEID. .

The demultiplexer 425 analyzes the PT value of the received packet, and if the PT value is a value between 72 and 76, inputs the received packet to the first RB layer 435 configured for the RTCP packet, and PT If it is a value other than 72 to 76, the received packet is input to the second RB layer 430 configured for the RTP packet. Here, the first RB layer 435 configured for the RTCP packet is composed of PDCP, RLC, etc., which is configured for RTCP packet processing, and the second RB layer 330 configured for RTP packet, is configured for PDCP packet processing. , RLC and the like.

The RTP packet processed by the second RB layer 430 is transferred from the MAC layer 440 to a transport channel, and the physical layer 445 receives the RTP packet according to a channel coding method and a channel coding rate of the corresponding transport channel. After processing, it transmits to the wireless channel. In addition, the RTCP packet processed by the first RB layer 435 is transferred from the MAC layer 440 to the transport channel, and the physical layer 445 receives the RTCP packet according to the channel coding scheme and channel coding rate of the corresponding transport channel. After processing, it transmits to the wireless channel.

Conversely, packets received from the wireless channel are routed to the first RB layer 460 for processing RTCP packets via the physical layer 450 and the MAC layer 455, and the second RB layer 465 for processing RTP packets. Each is transmitted, where a mapping relationship between the transport channel and the RB is used. The packets processed by the first or second RB layers 460 and 465 are delivered to the multiplexer 470, and the multiplexer 370 multiplexes the packets and outputs them as VoIP packets. VoIP packets are then delivered to the GTP tunnel layer 475, which transmits the VoIP packets to the CN.

5 is a flowchart illustrating an operation of a demultiplexer for separately transmitting RTC packets and RTCP packets according to an embodiment of the present invention, which is provided in a terminal and an RNC having a hierarchical structure of FIGS. 3 and 4. . Therefore, the demultiplexer described in FIG. 5 is located in the reverse transmission direction of the terminal and the forward transmission direction of the RNC, and serves to classify the RTP packet and the RTCP packet.

When the demultiplexer 425 of the RNC receives an IP / UDP packet from the CN in step 501 or the demultiplexer 325 of the terminal receives an IP / UDP packet from an upper layer, the demultiplexer 325 and 425 performs step 503. Proceed to analyze the PT value of the PT field (210, 220) included in the RTP header of the received packet. When the analyzed PT value of step 503 is determined to be a value between 72 and 76, the demultiplexers 325 and 425 determine the received packet as an RTCP packet and perform a first CPB and RLC process on the RTCP packet. Pass to layers 335 and 435. When the analyzed PT value of step 503 is determined to be a value other than 72 to 76, the demultiplexers 325 and 425 determine the received packet as an RTP packet to perform PDCP and RLC processing on the RTP packet. Transfer to the RB layer (330, 430).

For the above operation, the demultiplexer included in the terminal and the RNC should recognize the RB transmitting the RTP packet and the RB transmitting the RTCP packet during call setup, and the terminal and the RNC have relevant information. Must be communicated.

FIG. 6 is a flowchart illustrating a method of separately transmitting RTC packets and RTCP packets according to an embodiment of the present invention. In particular, FIG. 6 illustrates a UE (UE), a RNC, and a SGSN (Serving GPRS Support) of a UMTS network. A process of exchanging control signals between a Node) and a Gate GPRS Support Node (GGSN) is shown.

In FIG. 6, the SGSN is connected between the RNC and the GGSN to control packet flow, and the GGSN is connected to the SGSN and the CN to mean a network entity (NE) for controlling packet transmission and reception with the CN. In step 601, the UE (UE) exchanges a VoIP call setup signal with the other party to establish a call. The call establishment signal exchange is performed through a Session Initiation Protocol (SIP), and parameters necessary for call establishment are exchanged through a Session Description Protocol (SDP). Parameters exchanged through the SDP may include, for example, a type of media exchanged through a call, a required bandwidth, codec information, and the like. The terminal may determine whether the call to be set up is a VoIP call through the SDP parameter received in the call setup process.

Thereafter, in step 603, the UE transmits an Activate PDP Context Request Message (SGDP) Context Request Message (SGDP) to the SGSN in order to configure a radio bearer for packet transmission. The active PDP environment request message includes quality of service (QoS) information of the RTP packet. Here, the terminal recognizes the QoS information through the SDP parameter obtained in step 601. In addition, in step 603, if the call to be established is a call requiring transmission and reception of RTCP packets, such as a VoIP call, the terminal transmits the QoS information of the RTCP packet together with the active PDP environment request message. The QoS information may include a required bandwidth, priority or type of traffic in which the packet is transmitted.

In step 605, the SGSN receiving the active PDP environment request message transmits a RAB Assignment Request message (RAB) to the RNC in order to establish a radio bearer between the RNC and the UE. The RAB assignment request message includes QoS information of the RTP packet and the RTCP packet. In step 607, when the RNC receives the RAB allocation request message, the RNC sets up a radio bearer (RB) and a multiplexer / demultiplexer of the RNC based on the information included in the message.                     

Referring to step 607 in more detail, the RNC uses the QoS information of the RTP packet and the RTCP packet included in the RAB allocation request message to determine the configuration information of the RTP packet radio bearer and the configuration information of the RTCP packet radio bearer. The RNC sets up radio bearers for RTP packets and RTCP packets, respectively.

In addition, in step 607, the RNC configures a multiplexer / demultiplexer and then connects the multiplexer / demultiplexer with a radio bearer for an RTP packet and an RTCP packet, respectively. The RNC transmits a radio bearer setup message to the terminal. The radio bearer setup message includes configuration information and RTP indicator of the radio bearer for the RTP packet, configuration information and RTCP indicator of the radio bearer for the RTCP packet.

On the other hand, if the terminal receives the radio bearer setup message in step 607, the terminal configures a radio bearer for RTP packets, a radio bearer for RTCP packets and a multiplexer / demultiplexer, and then for the multiplexer / demultiplexer and RTP packets of the terminal And a radio bearer for an RTCP packet, respectively. In addition, the UE recognizes which of the radio bearers is a radio bearer for an RTP packet and which bearer is an RTCP radio bearer through an RTP indicator and an RTCP indicator. After completing the above procedure, the terminal transmits a response message to the RNC, and when the RNC receives the response message, step 607 is completed.

Thereafter, in step 609, a wired bearer is established between the RNC and the SGSN. This means that a forward GTP tunnel and a reverse GTP tunnel to service the VoIP call are established between the RNC and the SGSN. A detailed description of the process of setting the wire bearer is omitted since it is irrelevant to the gist of the present invention.

When the wireless and wired bearer setup is completed according to the above process, it is ready to exchange VoIP packets between the SGSN and the terminal. Thereafter, when the VoIP packet stream transmitted from the GGSN arrives at the RNC at any point according to step 611, the demultiplexer 425 of the RNC checks the PT value of the received packet to determine whether the received packet is an RTP packet or an RTCP packet. After the classification, the demultiplexing is performed according to the type of the divided packet in step 613. Accordingly, the RTP packet is transmitted to the terminal through the radio bearer for the RTP packet in step 615, and the RTCP packet is transmitted to the terminal through the radio bearer for the RTCP packet in step 617.

Conversely, although not shown in FIG. 6, when the VoIP packet is generated in the upper layer of the terminal, the demultiplexer 325 of the terminal checks the PT value of the received packet to distinguish whether the received packet is an RTP packet or an RTCP packet. Then, demultiplexing is performed according to the type of the divided packet. Accordingly, the RTP packet is transmitted to the RNC through the radio bearer for the RTP packet, and the RTCP packet is transmitted to the RNC through the radio bearer for the RTCP packet and transmitted to the counterpart terminal connected to the CN via the SGSN and the GGSN. Since the detailed description of this reverse process proceeds in a similar manner to those of FIG. 6, the detailed description thereof will be omitted.

In the above-described embodiment, the multiplexer / demultiplexer is located at the top of a packet data convergence protocol (PDCP) layer not shown. However, the structure in which the multiplexer / demultiplexer is located at the bottom of the PDCP layer cannot be excluded, and according to the present invention, even in such a hierarchical structure, the demultiplexing for the separate transmission of the RTP packet and the RTCP packet is based on the PT value described in FIG. It can be performed using.                     

Hereinafter, when the terminal and the multiplexer / demultiplexer of the RNC are located at the bottom of the PDCP layer, the terminal and the RNC according to the second embodiment of the present invention proposed to distinguish the RTP packet and the RTCP packet and transmit them through different radio bearers. The hierarchical structure of the multiplexer / demultiplexer and its operation will be described.

FIG. 7 is a hierarchical diagram illustrating an internal hierarchical structure of a UE that distinguishes RTC packets and RTCP packets and transmits them backwards according to an embodiment of the present invention.

In FIG. 7, VoIP voice data generated by the codec 705 of the terminal is input to the PDCP layer 723 via the RTP layer 710 and the UDP / IP layer 720. The PDCP layer 723 is an entity responsible for header compression and decompression. The header-compressed RTP packet in the PDCP layer 723 is input to the demultiplexer 725. RTCP packets are also delivered to demultiplexer 725 via RTCP layer 715, UDP / IP layer 720, and PDCP layer 723.

The PDCP layer 723 includes a header compression protocol called ROHC (Robust Header Compression). The header compression protocol includes a context ID (CID) for packet stream identification, a compressed IP / UDP / RTP header, and a payload. Compress into the included form. One header compression device (not shown) operated according to the header compression protocol can compress a plurality of packet streams individually, and the compressed packet streams are identified by the CID. In other words, in the packet structure of FIG. 2, the RTP packet and the RTCP packet are compressed by the same header compression device, and the RTP packet and the RTCP packet stream have different CIDs.                     

Accordingly, the demultiplexer 725 of the terminal can distinguish between the RTP packet and the RTCP packet by using the CID. However, since it is impossible to know which CID represents an RTP packet and which CID represents an RTCP packet, information for identifying the CID (hereinafter referred to as "CID verification information") is demultiplexer 725 through the PDCP layer 723. Is provided.

The PDCP layer 723 extracts the CID identification information by using a corresponding relationship between the CID and the PT value allocated to the packet while compressing the header of the received packet. That is, a specific packet stream (here, a packet stream means a set of packets having the same IP address and the same UDP port pair, and RTP packets generated from a specific VoIP call share the same IP address and UDP port, and thus are divided into one packet stream. Can be classified and can be classified as a single packet stream since the RTCP packets also share the same IP address and UDP port.) If the PT values of the value are between 72 and 76, the packet stream is an RTCP packet stream. If it has a value other than 72 to 76, it is an RTP packet stream.

The PDCP layer 723 checks whether a specific CID is an RTP packet stream or an RTCP packet stream, and then, using the demultiplexer 725, a correspondence relationship between the CID and the RTP packet stream, and a correspondence relationship between the CID and the RTCP packet stream. To the decode multiplexer 725 to the CID confirmation information. Accordingly, when the demultiplexer 725 recognizes the relationship between the packet stream received through the CID identification information and the CID, the demultiplexer 725 uses the CID value to convert the VoIP packet into an RTCP packet for the first RLC layer 735 or the RTP packet. Transfer to the second RLC layer 730 configured as.                     

In addition, the first RLC layer 735 configured for RTCP packet transmission may be operated as an RLC entity operating in an RLC acknowledgment mode (AM), for example, capable of retransmission, and a transport channel for processing RTCP packets. Connected with In addition, the second RLC layer 730 configured for RTP packet transmission may be an RLC entity operating in an RLC unacknowledged mode (UM), and is connected to a transport channel for processing an RTP packet.

VoIP packets processed through the first and second RLC layers 735 and 730 are transmitted over a wireless channel through the MAC layer 740 and the physical layer 745.

Conversely, packets received over the wireless channel are forwarded through the physical layer 750 and the MAC layer 755 to the first RLC layer 760 processing RTCP packets or the second RLC layer 765 processing RTC packets. do. At this time, the mapping relationship between the transport channel and the RLC layer is established in the call setup process. Thereafter, the packets processed by the first RCL layer 760 and the second RCL layer 765 are delivered to the multiplexer 770, and the multiplexer 770 forwards the delivered packets to the PDCP layer 773.

Then, the PDCP layer 773 restores the header of the received packet and transfers it to the UDP / IP block 775. Thereafter, the RTP packet is input to the codec 790 via the UDP / IP layer 775 and the RTP layer 785, and the codec 790 converts voice data carried in the RTP packet into real voice. The RTCP packet for control is delivered to the RTCP layer 780 via the UDP / IP layer 775.

FIG. 8 is a hierarchical diagram illustrating an internal hierarchical structure of a base station Node B and a base station controller RNC for forward transmission by dividing RTC packets and RTCP packets according to an embodiment of the present invention.

In FIG. 8, the physical layers 845 and 850 are located at the base station Node B, and the remaining layers are located at the RNC. In the hierarchical structure of FIG. 8, the operation of distinguishing between the RTP packet and the RTCP packet is essentially the same as that of the terminal. That is, when the PDCP layer notifies the demultiplexer 825 of the matching relationship between the CID and the packet stream, the demultiplexer 825 distinguishes between the RTP packet and the RTCP packet using the CID, and then transfers the demultiplexer 825 to the lower layer. Hereinafter, the interlayer operation of FIG. 8 will be described in more detail.

First, the RTC packet and the RTCP packet delivered from the CN are input to the PDCP layer 823 via the GTP tunnel layer 820. The PDCP layer 823 is responsible for compressing and restoring the header. In addition, the PDCP layer 823 analyzes the PT value of the packet stream to confirm the correspondence between the packet stream and the CID, and then verifies CID identification information indicating which CID corresponds to the RTP packet and which CID corresponds to the RTCP packet. It passes to the neutralizer 825.

After the demultiplexer 825 classifies the received packet based on the CID confirmation information, the RTCP packet is delivered to the first RLC layer 835 that processes the RTCP packet, and the RTP packet processes the second RLC that processes the RTP packet. Transfer to layer 830. The RTP packet or the RTCP packet is processed by the first and second RLC layers 835 and 830 and then transmitted to the wireless channel via the MAC layer 840 and the physical layer 845.

Conversely, a packet received over a wireless channel is passed through a physical layer 850 and a MAC layer 855 to a first RLC layer 860 that processes RTCP packets or a second RLC layer that processes RTP packets ( 865). At this time, the mapping relationship between the transport channel and the first and second RLC layers 860 and 865 is established during the call setup process.

The packets processed by the first or second RLC layers 860 and 865 are transferred to the multiplexer 870, and the multiplexer 870 multiplexes the transmitted packets to the PDCP layer 873. The PDCP layer 873 restores the header of the packet received from the multiplexer 870 and then transfers the header to the GTP tunnel layer 875. The GTP tunnel layer 875 then sends the VoIP packet to the CN. Meanwhile, since the overall control signal flow between the UE and the RNC, SGSN, and GGSN in the above-described two embodiments is the same as the control signal flow of the above-described embodiment, a detailed description thereof will be omitted.

As described above, in the first and second embodiments of the present invention, when the multiplexer / demultiplexer of the terminal and the RNC is not given separate information for distinguishing the RTP packet and the RTCP packet, the multiplexer / demultiplexer is RTP. A method for distinguishing between RTP packet and RTCP packet using PT values included in the packet and RTCP packet is presented.

In the third embodiment of the present invention to be described below, the UDP port (hereinafter referred to as "RTP port") number to be used by the RTP packet stream and the UDP port (hereinafter referred to as "RTCP port") number to be used by the RTCP stream are multiplexed / demultiplexed by the terminal and the RNC. The multiplexer / demultiplexer proposes a method of performing multiplexing / demultiplexing using the RTP port number and the RTCP port number. Here, since the RTP port number and the RTCP port number are known to the terminal to set up a call through SDP, the terminal inputs the RTP port number and the RTCP port number into its multiplexer / demultiplexer, and the multiplexer / demultiplexer of the RNC. The RTP port number and the RTCP port number can be informed.

Although various methods can be considered as a control message for the UE to inform the RNC of the RTP port number and the RTCP port number, in this embodiment, the active PDP environment request message and the RAB allocation request described in steps 603 and 605 of FIG. 6 are considered. It shows how to send messages including RTP port number and RTCP port number.

FIG. 9 is a flowchart illustrating a method of distinguishing and transmitting RTC packets and RTCP packets according to an embodiment of the present invention. This is similar to FIG. 6, which is a terminal (UE), a RNC, an SGSN, and a UMTS network providing a VoIP service. It shows the control signal exchange process between GGSN.

In step 901, the UE exchanges a VoIP call setup signal with the other party to establish a call. The call establishment signaling exchange is performed through the session initiation protocol (SIP), and the parameters necessary for call establishment are exchanged through the session description protocol (SDP). Parameters exchanged through the SDP may include, for example, a type of media exchanged through a call, a required bandwidth, codec information, and the like. If the call to be set up is a VoIP call, the RTP port number and the RTCP port number are also notified to the terminal through the SDP. The terminal may determine whether the call to be set up is a VoIP call through the SDP parameter received in the call setup process.

Thereafter, in step 903, the UE transmits an Activate PDP Context Request Message to the SGSN to configure a radio bearer between the RNC and the UE for packet transmission. The active PDP environment request message includes an RTP port number and an RTCP port number in addition to the QoS information of the RTP packet and the QoS information of the RTCP packet. Here, the terminal recognizes the QoS information through the SDP parameter obtained in step 901.

Upon receiving the active PDP environment request message in step 905, the SGSN transmits a RAB Assignment Request message to the RNC to establish a radio bearer between the RNC and the UE. The RAB assignment request message includes RTP port number and RTCP port number as well as QoS information of RTP packet and RTCP packet. When the RNC receives the RAB allocation request message in step 907, the RNC sets up a radio bearer (RB) and a multiplexer / demultiplexer of the RNC based on the information included in the message.

 In more detail with reference to step 907, the RNC uses the QoS information of the RTP packet and the QoS information of the RTCP packet included in the RAB allocation request message to determine the configuration information of the RTP packet radio bearer and the configuration information of the RTCP packet radio bearer. The RNC sets up radio bearers for RTP packets and RTCP packets, respectively.

After configuring the RNC multiplexer / demultiplexer, the multiplexer demultiplexer is connected to a radio bearer for an RTP packet and a radio bearer for an RTCP packet, and stores an RTP port number and an RTCP port number. The RNC transmits a radio bearer setup message to the terminal. The radio bearer setup message includes configuration information and RTP indicator of the radio bearer for the RTP packet, configuration information and RTCP indicator of the radio bearer for the RTCP packet.                     

On the other hand, when the UE receives the radio bearer setup message in step 907, the UE configures a radio bearer for RTP packets, a radio bearer for RTCP packets, and a multiplexer / demultiplexer, and then for the multiplexer / demultiplexer and RTP packet of the terminal. And a radio bearer for an RTCP packet, respectively. In addition, the UE recognizes which of the radio bearers is a radio bearer for an RTP packet and which bearer is an RTCP radio bearer through an RTP indicator and an RTCP indicator. Here, the terminal is already aware of the RTP port number and the RTCP port number through the SDP parameter.

After completing the process, the terminal transmits a response message to the RNC, and when the RNC receives the response message, step 907 is completed.

Thereafter, in step 909, a wired bearer is established between the RNC and the SGSN. This means that a forward GTP tunnel and a reverse GTP tunnel to service the VoIP call are established between the RNC and the SGSN. When the above processes are completed, the SGSN and the terminal are ready to exchange VoIP packets. After that, if the VoIP packet arrives at the RNC at any time as shown in step 911, the RNC uses the UDP port number (that is, the RTP port number and the RTCP port number) of the packet received in step 913 to RTP packet and RTCP packet. Demultiplexes the RTP packet to the radio bearer for the RTP packet and the RTCP packet to the radio bearer for the RTCP packet. The operation of the terminal classifying the VoIP packet into the RTP packet and the RTCP packet is also the same as above.

Conversely, although not shown in FIG. 9, when the VoIP packet is generated in the upper layer of the terminal, the demultiplexer of the terminal checks the UDP port number (that is, the RTP port number and the RTCP port number) of the received packet and the received packet is RTP. After classifying whether the packet is a packet or an RTCP packet, demultiplexing is performed according to the type of the divided packet. Accordingly, the RTP packet is transmitted to the RNC through the radio bearer for the RTP packet, and the RTCP packet is transmitted to the RNC through the radio bearer for the RTCP packet and transmitted to the counterpart terminal connected to the CN via the SGSN and the GGSN. Since the detailed description of this reverse process proceeds in a similar manner to those of FIG. 9, the detailed description thereof will be omitted.

As described above, according to the present invention, a method of easily distinguishing an RTP packet and an RTCP packet in a UMTS mobile communication system providing a VoIP service can be provided.

In addition, according to the present invention, it is possible to transmit and receive RTP packets and RTCP packets having different characteristics during VoIP communication through different radio bearers specialized for each traffic.

Claims (14)

In the method for transmitting a real-time transport packet in a mobile communication system providing a packet data service, Analyzing a field value included in a position corresponding to a payload type field of a real time transport protocol (RTP) packet from header information of the input packet; Checking whether the field value is included in a bit value of a specified range; And if the field value is out of the designated range, forwarding the input packet to a first radio bearer layer that processes a real time transmission control protocol (RTCP) packet. The method as claimed in claim 1, further comprising forwarding the input packet to a second radio bearer layer that processes the RTP packet when the field value is included in the designated range. The method as claimed in claim 1, wherein the field value is a bit value included in the payload type field in the case of the RTP packet. The method as claimed in claim 3, wherein the field value is a bit value included in a packet type field in the case of the RTCP packet. The method as claimed in claim 1, wherein the range of the bit value is set between 72 and 76 in decimal. The method as claimed in claim 1, wherein the real time transmission protocol packet (RTP) packet and the real time transmission control protocol (RTCP) packet are classified to be delivered to different radio bearers through a demultiplexer of a predetermined network entity. The method of claim 6, The network entity is characterized in that the terminal receiving the packet service. The method of claim 6, The network entity is characterized in that the base station controller for relaying the transmission and reception of the packet. In the method for transmitting a real-time transport packet in a mobile communication system providing a packet data service, Transmitting predetermined identification information for distinguishing between a real-time transmission protocol (RTP) packet and a real-time transmission control protocol (RTCP) packet from a packet data concentration protocol (PDCP) layer to a demultiplexer; And determining, by the demultiplexer, the input packet based on the identification information and transferring the received packet to a first radio bearer layer that processes the RTCP packet when the input packet corresponds to the RTCP packet. Said method. The method of claim 9, wherein the demultiplexer checks the input packet based on the identification information and delivers the received packet to a second radio bearer layer that processes the RTP packet when the input packet corresponds to the RTP packet. The method characterized in that it further comprises. The method as claimed in claim 9, wherein the PDCP layer checks a bit value included in a payload type field of the input packet and prepares the identification information. In the method for transmitting a real-time transport packet in a mobile communication system providing a packet data service, Informing the network entity of UDP port number and quality of service information used by the real-time transmission protocol (RTP) packet and the real-time transmission control protocol (RTCP) packet during call setup signaling; Setting, by the network entity, a first radio bearer for the RTP packet based on the UDP port number and the quality of service information; Setting, by the network entity, a second radio bearer for the RTCP packet based on the UDP port number and the quality of service information; Connecting, by the network entity, the first and second radio bearers to the demultiplexer using the UDP port number, respectively; And transmitting, by the demultiplexer, the input packet based on the UDP port number to the first or second radio bearer. An apparatus for transmitting a real-time transport packet in a mobile communication system providing a packet data service, A demultiplexer for analyzing a field value included in a position corresponding to a payload type field of a real-time transport protocol (RTP) packet from header information of an input packet and confirming whether the field value is included in a bit value of a specified range; A first radio bearer layer for delivering the input packet to a radio bearer for processing a real time transmission control protocol (RTCP) packet when the field value is out of the designated range; And a second radio bearer layer for delivering the input packet to a radio bearer for processing the RTP packet when the field value is included in the designated range. An apparatus for transmitting a real-time transport packet in a mobile communication system providing a packet data service, A packet data concentration protocol (PDCP) layer that checks the bit value included in the payload type field of the input packet and creates predetermined identification information that distinguishes a real-time transmission protocol (RTP) packet from a real-time transmission control protocol (RTCP) packet; , A demultiplexer for dividing the input packet into the RTCP packet and the RTP packet based on the identification information transmitted from the PDCP layer; A first radio bearer layer which processes the RTCP packet transmitted from the demultiplexer and transmits the RTCP packet to a radio bearer for an RTCP packet; And a second radio bearer layer which processes the RTP packet transmitted from the demultiplexer and transmits the RTP packet to a radio bearer for an RTP packet.

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