CN1710967A - Retransmission method of protocol data unit - Google Patents
Retransmission method of protocol data unit Download PDFInfo
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- CN1710967A CN1710967A CN 200410048775 CN200410048775A CN1710967A CN 1710967 A CN1710967 A CN 1710967A CN 200410048775 CN200410048775 CN 200410048775 CN 200410048775 A CN200410048775 A CN 200410048775A CN 1710967 A CN1710967 A CN 1710967A
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Abstract
After receiving service request from user equipment, service support node (SGSN) in general packet radio service (GPRS) assigns a tunnel end id (TEID) according to tunnel protocol (GTP), which possesses direction sign bit and context index bit of packet data protocol (PDP). After receiving a protocol data unit (G-PDU) from GTP tunnel SGSN determines forwarding direction of G-PDU based on value of direction sign bit in TEID and determines target network node the message to be forwarded to. Then, address of target network node to be forwarded in context of PDP is found based on context index bit of PDP. G-PDU is forwarded to the address of target network node based on the address. The invention reduces system overhead, and raises forwarding efficiency of G-PDU in SGSN.
Description
Technical field
The present invention relates to bearing technology field, GPRS (GPRS) tunnel in Wideband Code Division Multiple Access (WCDMA) (WCDMA) communication system, the protocol Data Unit retransmission method in particularly a kind of GTP tunnel.
Background technology
In WCDMA core net (CN), GPRS Tunnel Protocol (GTP) technology is applied to the data and the signaling transmission of GTP control plane and GTP user plane between universal mobile telecommunications system (UMTS)/GPRS core net GPRS Support Node (GSN), and wherein GSN comprises GPRS serving GPRS support node (SGSN) and GGSN (GGSN).Charging protocol GTP ' has also used the GTP technology simultaneously, in the user plane Iu interface, uses GTP user (GTP-U) agreement as the bearer context for data transmission technology between radio network controller (RNC) and SGSN.
The gprs system logical construction is with reference to shown in Figure 1, SGSN132 among the CN130 links by the RNC122 in Iu interface and the universal mobile telecommunications system grounding wireless access network (UTRAN) 120, RNC122 and base station (Node B) 121 links by Iub interface then, Node B121 links by Uu face and UE110 again, by logic control agreement (LLC), set up being connected between SGSN132 and the UE110, by setting up the GTP tunnel between SGSN132 and the RNC122, realize user data transmission is carried.
Among the CN130,, realize the interconnected of SGSN132 and SGSN132,, realize the user data exchange by setting up GTP tunnel by the Gn/Gp interface; Realize that by the Gn/Gp interface SGSN132 and GGSN135 link,, realized setting up passage between internet (INTERNET) 142 in SGSN132 and the external network 140, the interconnected of UE110 and internet 142 is provided by GTP tunnel; SGSN132 serves switching center's gateway (GMSC) 133 and can set up with public switch telephone network (PSTN) in the external network 140, Integrated Service Digital Network etc. 141 and connect by moving; By Gs interface, SGSN132 sends address information to mobile switching centre/Visited Location Registor (MSC/VLR) 131, and from the request of MSC/VLR131 paging receiving, realizes the related of packet-type business and non-grouping type business.
Preserved GPRS user data and routing iinformation in the attaching position register (HLR) 134, SGSN132 can realize visit to HLR134 through gn interface or GGSN135 through the Gc interface.
By above-mentioned network configuration, set up communicating by letter of UE110 and external network 140, and the main effect of SGSN is exactly the current location information that writes down UE in the network, and the message between realization and RNC, SGSN, the GGSN receives and sends.When UE when SGSN initiates service request, SGSN will distribute termination point of a tunnel sign (TEID) value for professional required communication network node RNC, GGSN or SGSN according to type of service, set up the GTP message and transmit required GTP tunnel.TEID is used to identify the Data-carrying tunnel between the GSN as Tunnel Identifier.When business is set up, will be a packet data protocol of this service creation (PDP) context in RNC, SGSN, the GGSN, this PDP Context is recorded in the local PDP Context tabulation.User access point title (APN), sequence number, procotol (IP) address of GGSN/SGSN/RNC, service quality a series of relevant parameters such as (Qos) of customer service have been write down in the PDP Context, for the GTP message is provided by the information that provides.
After SGSN receives the GTP message, judge by checking the type of message (Message Type) in the message whether the GTP message of receiving is GTP protocol Data Unit (G-PDU), if not, this message is the local reception message, does not need to transmit.If G-PDU need transmit.By checking that TEID value among the G-PDU judges the routing direction of G-PDU, and transmit required destination address, G-PDU is forwarded to destination address according to the G-PDU that writes down in the PDP Context.
For the allocation algorithm of TEID, common practice is since 0, distributes one by one, after arriving complete 1, distribute since 0 again, if during have PDP to discharge, sub-distribution under d/d TEID value reclaims and is used for.Since RNC only exist and SGSN between up GTP tunnel, GGSN only exist and SGSN between descending GTP tunnel, corresponding to same PDP Context, they have only the GTP tunnel of a direction.And for SGSN, the GTP message switching of existence and GGSN, RNC, SGSN that is to say, may there be corresponding same PDP Context in synchronization, and SGSN needs the GTP tunnel between foundation respectively and GGSN, RNC, the SGSN.If with the GTP tunnel between SGSN and GGSN, RNC, SGSN, simply be distributed into identical value, after SGSN receives the G-PDU message, can judge that this message is uplink message or downlink message, determines the message forwarding target network node according to the source IP address of input GTP message.
Adopt this method, after SGSN receives the G-PDU message, not only will find PDP Context at every turn, also need to judge that according to the IP address of the RNC/GGSN that preserves in the PDP Context this message is uplink message or downlink message, influences forward efficiency according to the TEID value.And the GGSN IP address in the PDP Context is the purpose IP address of SGSN to GGSN transmission message, and not indicating this address is GGSN sends source address from message to SGSN.When the GGSN mail returned on ground of incorrect address stored in the source address of message and the PDP Context, SGSN can't judge that this message is uplink message or downlink message.If UE carries out RNS service between SGSN when heavily distributing (SRNSRelocation), the original SGSN that inserts of UE does not have user's face IP address of former access SGSN in heavy request for allocation (the Forward Relocation Request) message of the forwarding that the SGSN of new access sends, like this, when the SGSN of new access receives the message that the SGSN of original access sends, can't judge the direction of this message.
In the prior art, for the message direction of judging that SGSN receives, with SGSN with after GTP tunnel between GGSN, RNC, the SGSN simply is assigned as different TEID values, for TEID sets up a concordance list, the GTP message direction and the PDP Context index of each TEID value correspondence of record in table.When receiving G-PDU, search the direction and the PDP Context index of the GTP message that writes down in the concordance list according to the TEID value, find PDP Context according to the PDP Context index again, take out G-PDU and transmit destination address, G-PDU is forwarded to destination address.Concrete G-PDU forwarding process is as shown in Figure 2:
Step 201:SGSN gives between RNC and the SGSN respectively, the GTP tunnel distribution T EID value between GGSN and the SGSN, between SGSN and the SGSN, sets up concordance list for the TEID value, writes down each TEID value pairing GTP message direction and PDP Context index.
Give an example, the index of the PDP Context of creating among GGSN, SGSN, the RNC is a PDP Context 2, and the GTP tunnel TEID value between RNC and SGSN is assigned as 1000; GTP tunnel TEID value between GGSN and SGSN is assigned as 1001; GTP tunnel TEID between SGSN and SGSN is assigned as 1002, the corresponding relation of TEID value that then writes down in the concordance list and message direction and PDP Context index is with reference to shown in Fig. 3: the message direction from RNC to SGSN is up, corresponding to the 1000 record GTP message directions of the GTP tunnel TEID value between RNC and SGSN is up, and the PDP Context index is a PDP Context 2; Message direction from GGSN to SGSN is descending, is descending corresponding to the 1001 record GTP message directions of the GTP tunnel TEID value between GGSN and SGSN, and the PDP Context index is a PDP Context 2; Message direction from SGSN to SGSN is for switching, and for switching, the PDP Context index is a PDP Context 2 corresponding to the 1002 record GTP message directions of the GTP tunnel TEID value between SGSN and SGSN.
When receiving G-PDU, find PDP Context index corresponding in the concordance list to be PDP Context 2 according to the TEID value after, can be directly searching index in the PDP Context tabulation is that the G-PDU that writes down in the PDP Context of PDP Context 2 transmits desired parameters.
Distribute the TEID value, write down corresponding GTP message direction and the PDP Context index of each TEID value in the concordance list, set up GTP tunnel, the reception and the forwarding of beginning GTP message.
Step 206: check the corresponding PDP Context index of up TEID value in the concordance list, carry out step 209 then.
Step 207: check the corresponding PDP Context index of descending TEID value in the concordance list, carry out step 210 then.
Step 208: check and switch the corresponding PDP Context index of TEID value in the concordance list, carry out step 211 then.
Step 209: the PDP Context index corresponding according to up TEID value finds target GGSN address in PDP Context, carry out step 212 then.
Step 210: the PDP Context index corresponding according to descending TEID value finds the Target RNC address in PDP Context, carry out step 213 then.
Step 211: in PDP Context, find the Target RNC address according to switching the corresponding PDP Context index of TEID value, carry out step 214 then.
Step 212: up G-PDU is forwarded to target GGSN address, finishes a up G-PDU message forwarding flow process.
Step 213: descending G-PDU is forwarded to the Target RNC address, finishes a descending G-PDU message forwarding flow process.
Step 214: will switch G-PDU and be forwarded to the Target RNC address, and finish one and switch G-PDU message forwarding flow process.
According to said method, when setting up GTP tunnel, need to give the TEID of GTP tunnel to set up concordance list, and in concordance list, write down the message direction and the PDP Context index of each TEID correspondence.After SGSN receives the G-PDU message, need check pairing message direction of TEID and the PDP Context index of the G-PDU that receives in the concordance list earlier, determine the forwarding target network node of G-PDU, and then find in the PDP Context address of transmitting target network node according to the PDP Context index, increase overhead, reduced the forward efficiency of G-PDU among the SGSN.
Summary of the invention
In view of this, main purpose of the present invention is to provide a kind of retransmission method of protocol Data Unit, reduces overhead, improves the forward efficiency of G-PDU among the SGSN.
According to above-mentioned purpose, the invention provides a kind of retransmission method of protocol Data Unit, the method includes the steps of:
A, when setting up GTP tunnel, distribute to GTP tunnel to have the TEID value of direction signs position and packet data protocol PDP Context index bit;
B, receive G-PDU after, determine the message routing direction according to the direction signs position in the TEID value of G-PDU, judge the target network node that message is transmitted;
C, find the address of the target network node of judging by step B in the PDP Context, G-PDU is forwarded to target network node according to this address according to the PDP Context index value among the TEID.
In this method, described steps A is specially: general packet radio service gprs serving GPRS support node SGSN gives between SGSN and the GGSN GGSN, the GTP tunnel between SGSN and the radio network controller (RNC), between SGSN and the SGSN, distribute respectively to have the TEID value of direction signs position and PDP Context index bit, set up GTP tunnel;
Among the step B, after SGSN receives G-PDU, determine the routing direction of G-PDU, judge the target network node of forwarding according to the direction signs position of TEID among the G-PDU.
The direction signs position of TEID value can be two in the described steps A; Determine the routing direction of G-PDU among the step B according to two direction signs positions of TEID value.
Further, the direction signs position of TEID value is 20 to 21 two in the described steps A; Determine the routing direction of G-PDU among the step B according to 20 to 21 two direction signs positions of TEID value.
The PDP Context of TEID value sign position is 0 to 19 in the described steps A; 0 to 19 PDP Context index value according to the TEID value among the step C is searched PDP Context.
By such scheme as can be seen, when setting up GTP tunnel, distribute for different GTP tunnels and have the TEID value of direction signs position and PDP Context index bit, make after receiving G-PDU, directly determine the message routing direction according to the direction signs position in the TEID value of G-PDU, judge that the target network node that message is transmitted is RNC or SGSN, directly find the target network node address that G-PDU transmits in the PDP Context according to the PDP Context index value among the TEID then, according to this address, G-PDU is forwarded to target network node.Like this, just need not give different TEID and set up concordance list for the direction of judging the GTP message, also just reduced and checked that concordance list finds the step corresponding to message routing direction and the PDP Context index of TEID after receiving the G-PDU message, reduce overhead, improved the forward efficiency of G-PDU among the SGSN.
Description of drawings
Fig. 1 is the gprs system building-block of logic;
Fig. 2 is the forwarding process figure of G-PDU in the prior art;
Fig. 3 is the corresponding relation schematic diagram of TEID value and message direction and PDP Context index in the concordance list;
Fig. 4 is the G-PDU forwarding process figure according to the embodiment of the invention;
Fig. 5 is according to embodiments of the invention TEID value distribution method schematic diagram.
Embodiment
For making the purpose, technical solutions and advantages of the present invention clearer, by the following examples, and with reference to accompanying drawing, the present invention is described in more detail.
Core concept of the present invention is: when setting up GTP tunnel, distribute for different GTP tunnels and have the TEID value of direction signs position and PDP Context index bit, make receive G-PDU after, determine the message routing direction according to the direction signs position in the TEID value, judge the target network node that message is transmitted, find the target network node address that message is transmitted in the PDP Context according to the PDP Context index value among the TEID then,, G-PDU is forwarded to target network node according to this address.
Lift a preferred embodiment of the present invention.The RNS service of carrying out between SGSN as UE heavily divides timing, and the GTP tunnel between the SGSN that SGSN sets up and UE inserted originally that needs newly to insert obtains the management information to UE, creates new PDP Context., also need to set up reception and the transmission that GTP tunnel carries out the GTP message respectively in order to carry out service with stylish SGSN with GGSN, RNC to UE.New SGSN carries out the distribution of TEID value and GTP message forwarding process as shown in Figure 4 to each GTP tunnel of setting up:
Step 401:SGSN gives each GTP tunnel distribution T EID value.The distribution method of TEID value as shown in Figure 5, at first with 0 to 19 of TEID value as the PDP Context index bit, insert the PDP Context index value of SGSN,, insert the direction signs value then with 20 to 21 two direction signs positions of TEID value as the GTP message for this service creation.The direction signs position of GTP tunnel between RNC and SGSN is inserted 00, and the GTP message direction from RNC that expression SGSN receives is up; The direction signs position of GTP tunnel between GGSN and SGSN is inserted 01, and the GTP message direction from GGSN that expression SGSN receives is descending; The original SGSN that inserts of UE inserts 10 to the direction signs position of GTP tunnel between SGSN, and the GTP message direction of the SGSN that inserts from the UE principle that expression SGSN receives is descending switching.Distribute the TEID value, set up the GTP message and transmit required GTP tunnel.
Step 402~403:SGSN receives the GTP message, checks the type of message in the GTP message, judges whether the GTP message of receiving is G-PDU.If not G-PDU, the GTP message is the local reception message, does not need to transmit, and withdraws from forwarding process; If be G-PDU, need transmit message, carry out step 404.
Step 404: 20 to 21 two direction signs values judging TEID among the G-PDU are 00,01, still 10.If be 00, the G-PDU that receives is a uplink message, and the forwarding target is GGSN, then carry out step 405; If be 01, the G-PDU that receives is a downlink message, and the forwarding target is RNC, then carry out step 406; If be 10, the G-PDU that receives is descending switching message, and the forwarding target is RNC, then carry out step 407.
Step 405: find PDP Context in the PDP Context tabulation according to 0 to 19 the PDP Context index value of TEID among the G-PDU, take out the GGSN address that up G-PDU transmits target in the PDP Context, carry out step 408 then.
Step 406: find PDP Context in the PDP Context tabulation according to 0 to 19 PDP Context index value of TEID, take out the RNC address that descending G-PDU transmits target in the PDP Context, carry out step 409 then.
Step 406: find PDP Context in the PDP Context tabulation according to 0 to 19 PDP Context index value of TEID, take out the RNC address that descending switching G-PDU transmits target in the PDP Context, carry out step 410 then.
Step 417: up G-PDU is forwarded to target GGSN, finishes the forwarding process of a up G-PDU.
Step 416: descending G-PDU is forwarded to Target RNC, finishes the forwarding process of a descending G-PDU.
Step 417: descending switching G-PDU is forwarded to Target RNC, finishes the forwarding process of a descending switching G-PDU.
In the above embodiments, when setting up the GTP message and receiving and send required GTP tunnel, SGSN has distributed 20 to 21 to be the TEID value of PDP Context index bit for direction signs position and 0 to 19 for different GTP tunnels, after SGSN receives G-PDU, determine the routing direction of G-PDU to the value in 21 two according to 20 among the TEID, judge the target network node that message is transmitted, find target network node address in the PDP Context according to 0 to 19 PDP Context index value among the TEID then, according to this address G-PDU is forwarded to target network node, like this, just do not need to set up concordance list to TEID, also just reduced and checked that the TEID concordance list determines the direction of message and find the step of PDP Context index, reduce overhead, improved the forward efficiency of G-PDU.
Abovely lift preferred embodiment, the purpose, technical solutions and advantages of the present invention are further described, institute is understood that, the above only is embodiments of the invention, not in order to restriction the present invention, all any modifications of being done within the spirit and principles in the present invention, be equal to replacement etc., all should be included within the scope of the present invention.
Claims (5)
1, a kind of retransmission method of protocol Data Unit is characterized in that comprising following steps:
A, when setting up GPRS tunnel protocol GTP tunnel, distribute termination point of a tunnel sign TEID value to GTP tunnel with direction signs position and packet data protocol PDP Context index bit;
B, receive GTP user data cell G-PDU after, determine the message routing direction according to the direction signs position in the TEID value of G-PDU, judge the target network node that message is transmitted;
C, find the address of the target network node of judging by step B in the PDP Context, G-PDU is forwarded to target network node according to this address according to the PDP Context index value among the TEID.
2, the method for claim 1, it is characterized in that, described steps A is: general packet radio service gprs serving GPRS support node SGSN gives between SGSN and the GGSN GGSN, the GTP tunnel between SGSN and the radio network controller (RNC), between SGSN and the SGSN, distribute respectively to have the TEID value of direction signs position and PDP Context index bit, set up GTP tunnel;
Among the step B, after SGSN receives G-PDU, determine the routing direction of G-PDU, judge the target network node of forwarding according to the direction signs position of TEID among the G-PDU.
3, the method for claim 1 is characterized in that, the direction signs position of the value of TEID described in the steps A is two;
Determine the routing direction of G-PDU among the step B according to two direction signs positions of TEID value.
4, the method for claim 1 is characterized in that, the direction signs position of the value of TEID described in the steps A is 20 to 21 two;
Determine the routing direction of G-PDU among the step B according to 20 to 21 two direction signs positions of TEID value.
As claim 1,3 or 4 described methods, it is characterized in that 5, the PDP Context sign position of the value of TEID described in the steps A is 0 to 19;
0 to 19 PDP Context index value according to the TEID value among the step C is searched PDP Context.
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| CN101090362B (en) * | 2006-06-20 | 2010-04-14 | 中兴通讯股份有限公司 | Method for single channel consultation in group field |
| WO2010066179A1 (en) * | 2008-12-08 | 2010-06-17 | 华为技术有限公司 | Data transmission method, system and device |
| WO2011011945A1 (en) * | 2009-07-29 | 2011-02-03 | 中兴通讯股份有限公司 | Message-sending method and serving gprs support node |
| WO2011057512A1 (en) * | 2009-11-13 | 2011-05-19 | 中兴通讯股份有限公司 | Method, operator edge device and system for ethernet service accessing bearing tunnels |
| CN101415013B (en) * | 2008-11-27 | 2011-09-28 | 普天信息技术研究院有限公司 | Method for identifying endpoint designation data packet |
| CN101136853B (en) * | 2007-09-27 | 2012-04-25 | 华为技术有限公司 | Data routing method |
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| CN104869668A (en) * | 2015-02-13 | 2015-08-26 | 北京集奥聚合科技有限公司 | Method for access platform to support GTP signaling |
| CN105379199A (en) * | 2014-06-16 | 2016-03-02 | 华为技术有限公司 | Service packet distribution method and apparatus |
| WO2017113354A1 (en) * | 2015-12-31 | 2017-07-06 | 华为技术有限公司 | Data packet transmission method and device |
| CN108377493A (en) * | 2016-11-21 | 2018-08-07 | 华为技术有限公司 | Connect method for building up, equipment and system |
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| US8218535B1 (en) * | 2000-07-04 | 2012-07-10 | Nokia Corporation | Method and device for attaching a user equipment to a telecommunication network |
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| CN101090362B (en) * | 2006-06-20 | 2010-04-14 | 中兴通讯股份有限公司 | Method for single channel consultation in group field |
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| CN101415013B (en) * | 2008-11-27 | 2011-09-28 | 普天信息技术研究院有限公司 | Method for identifying endpoint designation data packet |
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| WO2011011945A1 (en) * | 2009-07-29 | 2011-02-03 | 中兴通讯股份有限公司 | Message-sending method and serving gprs support node |
| CN101990174A (en) * | 2009-07-29 | 2011-03-23 | 中兴通讯股份有限公司 | Message sending method and SGSNs (Serving GPRS (General Packet Radio Service) Supporting Node) |
| WO2011057512A1 (en) * | 2009-11-13 | 2011-05-19 | 中兴通讯股份有限公司 | Method, operator edge device and system for ethernet service accessing bearing tunnels |
| US9894554B2 (en) | 2011-04-07 | 2018-02-13 | Zte Corporation | Packet data network gateway and terminal mobility management system |
| WO2012136097A1 (en) * | 2011-04-07 | 2012-10-11 | 中兴通讯股份有限公司 | Packet data network gateway and terminal mobility management system |
| CN105379199A (en) * | 2014-06-16 | 2016-03-02 | 华为技术有限公司 | Service packet distribution method and apparatus |
| CN105379199B (en) * | 2014-06-16 | 2019-07-09 | 华为技术有限公司 | Service message distribution method and device |
| CN104869668A (en) * | 2015-02-13 | 2015-08-26 | 北京集奥聚合科技有限公司 | Method for access platform to support GTP signaling |
| CN104869668B (en) * | 2015-02-13 | 2018-05-29 | 北京集奥聚合科技有限公司 | Method for access platform to support GTP signaling |
| WO2017113354A1 (en) * | 2015-12-31 | 2017-07-06 | 华为技术有限公司 | Data packet transmission method and device |
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| CN108377493B (en) * | 2016-11-21 | 2021-01-29 | 华为技术有限公司 | Connection establishment method, device and system |
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