RU2407164C2 - Method of readdressing data stream transmission channel in radio communication system - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: when handing over subscriber connection from a first radio network node to a second radio network node, an access gateway is determined for processing traffic, which is more suited for the second radio network node, the traffic transmission channel is altered; and the data stream is transmitted by a traffic transmission node to the second radio network node over the said altered traffic transmission channel.

EFFECT: optimisation of transmitting signal messages and minimisation of overloading in a network when a mobile terminal changes a data stream transmission gateway.

25 cl, 13 dwg

Description

FIELD OF THE INVENTION

[1] The present invention relates to a developing (expanded) universal mobile communication system “E-UMTS” and, in particular, to a method for efficiently forwarding (redirecting) a path / data transmission channel in the case when the mobile terminal changes the data transmission gateway.

State of the art

[2] Figure 1 illustrates the network structure of the evolving universal mobile communications system "E-UMTS" in which well-known technical solutions and the present invention can be applied.

[3] The developing universal mobile communication system “E-UMTS” was developed to develop the universal mobile communication system “UMTS”, for which the 3GPP technical group prepares the main specifications applicable to it. The E-UMTS system can be classified as the LTE system - long-term evolutionary development.

[4] As shown in figure 1, the network of the developing universal mobile communication system "E-UMTS" consists of a network of 20 "E-UTRAN" (developing terrestrial radio access network of the system "E-UMTS") and cell 10 "EPC" (Evolved Packet Core - an emerging packet-switched network). Network 20 “E-UTRAN” contains a terminal (“UE” - subscriber equipment)), a base station 21 (“eNB” or “eNode B”) 21 and an access gateway 11 AG (which may also be referred to as “MME / UPE”) . The “AG” access gateway 11 may also consist of a node for processing a user data stream and a node for processing a control data stream. The access gateway node “AG”, designed to process a new user data stream, and the access gateway node “AG”, designed to process a control data stream, can exchange data with each other via a newly defined interface.

[5] One or more cells may exist in one eNode B (eNB) 21 base station, and an interface may be used between the eNode B base stations for transmitting a user data stream and a control data stream.

[6] The EPC network 10 may comprise an access gateway 11 “AG”, a user registration node of a “UE” terminal, and the like. In addition, in the terrestrial radio access network of the UMTS system shown in FIG. 1, an interface may be used that interconnects the E-UTRAN 20 ground network 20 and the EPC network 10. The "S1" interface can connect multiple nodes (for example, according to the "many points - many points" scheme) of the base stations 21 "eNode B" and access gateways 11 "AG". The “eNode B” base stations are connected to each other using the “X2” interface, which is always present between adjacent “eNode B” base stations in the structure of the cellular network.

[7] The layers of the air interface protocol between the UE and the network can be divided into the first level (L1), the second level (L2) and the third level (L3) based on the three lower layers of the standard open system interconnection (OSI) model, well known in communication systems.

[8] The first level (LI) provides a service for transmitting information using a physical channel, and the RRC radio resource control level located at the third level (L3) serves to control radio resources between the terminal and the network, while the RRC radio resource control level "Exchanges" RRC messages "between the terminal and the network. The radio resource control level “RRC” can be distributed in such a way that it is located in network nodes, for example, at base stations “eNode B” and in access gateways “AG”, etc. or only at “eNode B” base stations or “AG” access gateways.

[9] FIG. 2 illustrates a control plane structure of a radio access interface protocol between a terminal and a UTRAN based on various standards of a 3GPP wireless access network.

[10] The radio access interface protocol has horizontal layers, including a physical layer, a data link layer and a network layer, as well as vertical planes, including a user plane for transmitting information data, and a control plane for transmitting control signals.

[11] The protocol layers can be divided into the first level (L1), the second level (L2) and the third level (L3) based on the three lower levels of the standard open system interconnection (OSI) model, well known in communication systems. Now we describe each level of the control plane of the radio protocol in figure 2 and the user plane of the radio protocol in figure 3.

[12] The first or physical layer provides a service for transmitting information to an upstream layer using a physical channel. The physical layer is connected to the MAC access control layer located at the upper level, a transport channel through which data is transferred between the MAC access control layer and the physical layer. Between the various physical layers, namely the physical layers of the transmitting side and the receiving side, data is transmitted over the physical channel.

[13] The Layer 2 MAC access control layer provides a service to the RLC radio link control layer, an upstream layer, through a logical channel. The RLC radio link control layer of the second layer reliably supports data transmission. The function of the RLC radio control layer may be implemented by a functional unit within the MAC access control layer, in which case the RLC radio control layer may be absent. The level of the packet data convergence protocol "PDCP" of the second level has the function of header compression, designed to reduce the amount of unnecessary control information, so that the data transmitted using packets in accordance with the Internet Protocol - "IP packets", for example, over IPv4 "Or" IPv6 ", can be efficiently transmitted over a radio interface with a relatively small bandwidth.

[14] The RRC radio resource control layer located at the bottom of the third level (L3) is defined only in the control plane and controls the transport channels with respect to the configuration, re-configuration and release of the RB radio channels. Here, the RB channel refers to the service provided by the second layer (L2) for data transmission between the terminal and the UTRAN.

[15] The downlink transport channels for transmitting data from the network to the terminal include: a BCH broadcast channel for transmitting system information, as well as a SCH downlink shared channel for transmitting a user data stream or control messages . The provision of multicast or broadcast services, the transmission of a data stream or control messages over a downlink can be done via a downlink shared channel "SCH" or through a separate downlink multicast service "MCH".

[16] The uplink transport channels for transmitting data from the terminal to the network include a random access channel “RACH” for transmitting an initial control message and an uplink shared channel “SCH” for transmitting a user data stream and control messages.

Description of the invention

Technical problem

[17] In the known technical solution, when the mobile terminal cannot be connected to the gateway (for example, the “AG” access gateway) to transmit traffic, the mobile terminal does not support the current connection for use due to its further movement, or when the gateway cannot to maintain stability in relation to other operations, the mobile terminal switches its connection to the gateway corresponding to the base station into which zone it has moved.

[18] However, in this regard, switching to a new gateway leads to an overload of the network data stream due to the exchange of contextual data between the gateways and the transmission of signaling messages between many base stations and gateways, etc.

Technical solution

[19] One of the typical functions of the present invention is to propose a method for forwarding a data flow path of a mobile terminal to optimize signaling so as to minimize network congestion when the mobile terminal changes the data flow gateway.

[20] To implement at least the above function in whole or in part, the present invention provides a method for forwarding a data flow path in a mobile communication system, which may include the following steps: when the mobile terminal transfers the subscriber connection from the first radio network node to the second a radio network node, determining a gateway for processing a data stream and most suitable for a second radio network node; changing the transmission path of the data stream by switching to the specified specific gateway; and transmitting the data stream by the data stream transmitting node to the second radio network node through said modified data stream transmission path.

[21] The first radio network node may be the base station to which the mobile terminal is currently connected to receive the service, and the second radio network node may be the base station to which the mobile terminal must move to receive the service.

[22] In the method for redirecting the data flow transmission path, the step of changing the data flow transmission path includes the following steps: transmitting, by the second radio network node, a message requesting redirection to the specified first gateway; transmitting, by the first gateway that received the call forwarding, messages requesting optimization of the path to the gateway from which the terminal previously received the service; and transmitting, by the second gateway, a response message to the first gateway and informing the data flow transmission node within the network that the data flow transmission path has changed.

[23] The redirect request message may include terminal context information, such as authentication information, security information, and compression related information.

[24] The path optimization request message may include context information and terminal identification information.

[25] The first gateway registers the terminal in the terminal list of the first gateway and manages itself in accordance with the specified response message, and the second gateway can remove the context information associated with the terminal and also remove the terminal from the list of terminals managed by it.

[26] The foregoing and other objects, features, aspects and advantages of the present invention will be more apparent from the following detailed description of the present invention in conjunction with the accompanying drawings.

[27] Brief Description of the Drawings

[28] The accompanying drawings, included in the description for a better understanding of the invention and forming part of this description, illustrate embodiments of the present invention and together with the description serve to explain the principles of the invention.

[29] In the drawings:

[30] Figure 1 shows an example of a network structure of the developing universal mobile communication system "E-UMTS" - a mobile communication system in which known technical solutions and a mobile terminal can be applied.

[31] Figure 2 shows an example of a control plane structure of a radio interface protocol between a terminal and a UTRAN based on the 3GPP wireless access network specification.

[32] Figure 3 shows an example of a user plane structure of a radio interface protocol between a terminal and a UTRAN based on the 3GPP wireless access network specification.

[33] Figure 4 shows an example of a network structure model for explaining the forwarding method in accordance with the present invention, namely, the configuration of the core network when forwarding the AG gateway.

[34] Figure 5 shows an example of the transmission of a data stream (eg, packet data) between the base stations “eNB” when moving the terminal from the source base station “seNB” to the target base station “teNB”.

[35] Fig. 6 is a diagram showing the transmission of a data stream from the sAG to the target base station teNB when the terminal moves from the source base station seNB to the target base station teNB.

[36] Figure 7 shows the transmission of a data stream when moving a terminal from the source base station "seNB" to the target base station "teNB", but there is no data channel between the gateway "sAG" and the base station "teNB".

[37] Figure 8 shows an example of forwarding the optimal gateway "AG" to the target base station "teNB" and transmitting the data stream when moving the terminal from the source base station "seNB" to the target base station "teNB".

[38] FIG. 9 shows a method for forwarding a packet data channel in accordance with the present invention.

[39] FIG. 10 shows a method for forwarding a packet data channel by requesting forwarding at the “AG” gateway, followed by channel switching.

[40] Figures 11 and 12 show the procedure for forwarding the AG gateway using a terminal.

[41] Figure 13 shows an example of the structure of a mobile terminal in accordance with the present invention.

Description of Embodiments of the Present Invention

[42] One aspect of the present invention is the understanding by the authors of the present invention of the disadvantages of the known technical solutions mentioned above, which are further explained below. Based on this understanding, the present invention has been developed.

[43] Although the present invention has been described using an example of its implementation in a UMTS-type mobile communication system developed in accordance with 3GPP specifications, it can also be used in other communication systems operating in accordance with other standards and specifications.

[44] As network technology continues to evolve, it is suggested that the RNC radio network controllers may no longer be needed in future networks, as advanced Node B base stations or other types of network objects (for example, so-called access gateways) can perform operations that are now performed by existing RNC radio network controllers. This long-term evolutionary development provides the additional support needed to develop improved radio link management technologies for use in commissioning new terminals (or to create new user channels) and to support newly developed advanced services for a larger number of network-managed terminals.

[45] The present invention provides a method for redirecting (redirecting) a data stream transmission path capable of minimizing network congestion for transmitting a data stream and minimizing an unnecessary signaling process when the mobile terminal is forced to change the radio network “AG” access gateway due to the movement of the radio terminal.

[46] Thus, when the mobile terminal changes its connection with the first radio network node with which the mobile terminal is currently connected to the second radio network node, the wireless communication system changes or re-establishes the gateway node for processing the data stream most suitable for a second radio network node, thereby optimizing transmission efficiency.

[47] Preferably, the first radio network node may be a source base station “seNB” to which a mobile terminal is currently connected to receive a service, and the second radio network node may be a target base station “teNB” to which a mobile terminal is about to transition to receive a service .

[48] FIG. 4 is an example of a network structure model for explaining a forwarding method in accordance with the present invention, namely, a core network configuration related to forwarding of an “AG” access gateway.

[49] As shown in FIG. 4, the Inter-AS transit autonomous system 100 is a higher-level network node, and the service transmitted to the terminal is transmitted to the “AG” access gateways (the source sAG 200 and the target gateway "tAG" 210) through a transit autonomous system 100 "Inter-AS" (for example, a station transmitting a data stream). A transit autonomous station can serve as a “link” when interfacing with another network. Alternatively, a network node located at a level higher than the “AG” access gateways and performing the bind function when interfacing with another network can act as a transit autonomous system 100 “Inter-AS”. AG access gateways connect to each other directly or indirectly. For example, two “AG” access gateways can be connected to each other with or without other network nodes between them.

[50] An access gateway 200 “sAG” (source access gateway “AG”) is an access gateway “AG” to which a terminal is currently connected to receive services. The source sAG access gateway 200 may have terminal related information. Information regarding the terminal may include authentication information, security information, compression information, service information, location tracking data “TA” (location zones), etc. Target gateway 200 "sAG" uses the packet data convergence protocol "PDCP", a security-related protocol, and compression-related protocols with respect to the terminal.

[51] Access gateway 210 “tAG” (target access gateway “AG”) is an access gateway “AG” to which the terminal switches after moving to the target base station “teNB” 300 (target “teNB”), and the source base station A “seNB” 310 (source “seNB”) is a node of a base station to which a terminal is connected to receive a service. Through the base station, the terminal is assigned radio resources, and it receives traffic through the radio interface. If the terminal is about to move from the source base station "seNB" 300 to the target base station "teNB" 310, it disconnects from the source base station "seNB" 300 and establishes a new connection with the target base station "teNB" 310 (ie, it disconnects connection to the source base station "seNB" and creates a new connection to the target base station "teNB"). In this case, the target base station "teNB" is usually connected by an interface (X2) to the source base station "seNB" 300, through which packet data can be transmitted between these base stations "eNB". One base station through the interface (S1) can perform packet data to multiple access gateways "AG".

[52] FIG. 5 illustrates an example of transmitting a data stream (eg, packet data) between an “eNB” base station when moving a terminal from a source base station “seNB” 300 to a target base station “teNB” 310. As shown in FIG. 5 when moving the terminal from the source base station "seNB" 300 to the target base station "teNB" 310, packet data transmission is performed between the source base station "seNB" 300 and the target base station "teNB" 310 until the transmission of the subscriber connection from one base station to another, while the target base camp Ia «teNB» 310 receives completion information transmission of the subscriber connection after transmission of the source base station «seNB» 300 on command to transfer the subscriber terminal connections.

[53] FIG. 6 is a diagram illustrating the transmission of a data stream from a source access gateway “sAG” 200 to a target base station “teNB” 310 while moving the terminal from the source base station “seNB” 300 to the target base station “teNB” 310. Figure 6 shows the case when the terminal, after completing the transfer of the subscriber connection from one base station to another, moves to the target base station "teNB" 310, the data path from the source access gateway "sAG" 200 is updated so that traffic can be transmitted directly to target base station teNB, not to the source base station "seNB".

[54] Figure 7 shows the transmission of data flow when moving the terminal from the source base station "seNB" 300 to the target base station "teNB" 310, but the data path between the source access gateway "sAG" 200 and the target base station "teNB" 310 is missing. In Fig. 7, when moving the terminal from the source base station "eNB" 300 to the target base station "teNB" 310, immediate connection is impossible, because there is no direct data channel from the source access gateway "sAG" 200 to the target base station "teNB" 310 or due to other problems, therefore, the transmission of the data stream should be performed through the target access gateway "tAG" 210, to which the target base gateway can be connected station "teNB" 310.

[55] In the cases shown in FIGS. 6 and 7, due to the fact that traffic can be transmitted to the terminal through a path other than optimal, additional delays in the transmission of the data stream (traffic) may occur. In addition, there may be a problem associated with the transmission of the data stream related to the data transfer load or throughput of the original sAG access gateway, etc.

[56] Therefore, as shown in FIG. 8, the access gateway (target gateway “tAG”) most suitable for the base station “eNB” to which the terminal is connected must be reassigned to transmit the data stream through the optimized path.

[57] Figure 8 shows an example of forwarding with switching to the optimal access gateway "AG" for the target base station "teNB" and transmitting the data stream when moving the terminal from the source base station "seNB" 300 to the target base station "teNB" 310;

[58] FIG. 9 illustrates a method for optimizing a packet data path by forwarding an “AG” access gateway, and in particular, presents a method for forwarding an “AG” access gateway during a data stream transmission, as shown in FIGS. 6 and 7 .

[59] As shown in FIG. 9, the terminal is in an active mode in a state of receiving or transmitting a data stream. During the transfer of the subscriber connection from one base station to another during the terminal’s movement from the source base station “seNB” to the target base station “teNB”, the terminal receives traffic through the source base station “seNB” (Fig. 5: “Inter-AS system” "(100) -> gateway" sAG "(200) -> station" seNB "(300) -> station" teNB "(310) -> terminal).

[60] After completion of the transmission of the subscriber connection from one base station to another, the terminal can receive traffic directly from the target teNB base station through the target sAG access gateway (Fig.6: Inter-AS system (100) -> gateway "SAG" (200) -> station "teNB" (310) -> terminal) or can receive traffic through the target gateway "tAG", i.e. new access gateway "AG" (Fig. 7: system "Inter AS" (100) -> gateway "sAG" (200) -> station "seNB" (210) -> station "teNB" (310) -> terminal) .

[61] Accordingly, first, the target access gateway “teNB” 310 can check the operation of the terminal, namely, the state of transmission or reception of the data stream. In this case, the terminal can be in the active mode in which it transmits or receives traffic, or in the quasi-active mode in which it is in the active state, but transmits or receives small traffic or does not transmit and does not receive any data stream. The quasi-active mode is similar to the standby mode, but differs from it in that the terminal is located and held in a state of connection with the base station “eNB”, to which the context data of the terminal “UE” is connected. It is assumed here that the terminal transmitting or receiving traffic in the active mode is changed so that it is in the quasi-active mode, since the transmission and reception of data are suspended. When a terminal is checked for its presence in quasi-active mode, the target base station “teNB” 310 determines the most efficient access gateway “AG” (target access gateway “tAG”) (which can be determined by the operator based on characteristics such as optimizing the flow path data, information load, user load, etc.) and transmits to the target access gateway “tAG” 210 a request message to redirect the access gateway “AG” (step S10).

[62] The redirect request message for the “AG” access gateway may contain context data of the “UE” terminal or similar information associated with the terminal. The terminal context data may include authentication information, security information, and compression related information. In the message requesting the redirection of the access gateway “AG”, additional context data of the terminal “UE” and information of a different type may be included. In this case, the terminal can be put into standby mode or left in quasi-active mode. To this end, the target base station "teNB" 310 may transmit to the terminal a message requesting to change or save the state of the terminal.

[63] When the target access gateway "tAG" 210 receives from the target base station "teNB" 310 a request message to redirect the access gateway "AG", it transmits to the source access gateway "sAG" a request for path optimization for the gateway "AG" (step S11). In this case, the path optimization request message for the “AG” gateway may contain the context data of the “UE” terminal, as well as identifying information or, if necessary, may contain authentication information and security information.

[64] After receiving a request message to optimize the AG gateway path, the source sAG 200 may send to the target tAG access gateway a response message to the AG gateway path optimization request containing contextual data, for example, information about authentication and security information associated with the terminal (step S12). When the target access gateway “tAG” 210 receives a response message to the request for optimization of the path of the access gateway “AG”, it can register or add the terminal to its list of terminals (which can be controlled by the target access gateway “tAG”). The original sAG 200 access gateway may delete or add contextual data associated with the terminal, or exclude the terminal from its list of terminals. Or, the original sAG access gateway can store partially or entirely the context data of the UE.

[65] The source access gateway "sAG" 200 requests the "Inter-AS" 100 system or a server associated with the distribution of the data stream or providing a service within the network to change the transmission path of the data stream from the terminal to the target access gateway "tAG" 210 instead of the source access gateway “sAG” 200, using the path switching message (step S13).

[66] After receiving the path switching message, the Inter-AS system 100 can check the traffic situation (information load, etc.), switch the data flow path associated with this service, and start transmitting the data flow for the terminal through target access gateway "tAG" 210, and not through the source access gateway "sAG" 200. Accordingly, traffic is directly transmitted to the target base station "teNB" 310 from the "Inter-AS" 100 system through the target access gateway "tAG" 210 its delivery to the terminal through an optimized path. In addition, the data stream transmission path can change when the conditions of the information load change substantially (i.e., when the information load is greater than a predetermined threshold value), even after the data stream transmission path is previously created.

[67] We will describe in detail with reference to FIG. 10 a request for forwarding the access gateway “AG” using delayed path switching.

[68] The basic assumptions and processes presented in FIG. 10 correspond to the processes presented in FIG. 9. Accordingly, the first step and the second step in FIG. 9 are similarly performed in FIG. 10. In the third step, the target access gateway "tAG" 210 may receive a response message to the request for optimization of the path of the access gateway "AG" and confirm the request for optimization of the path of the access gateway "AG". In the fourth step, the target access gateway tAG 210 may send a message about switching to the Inter-AS system 100 after receiving a request to optimize the path of the access gateway AG. After receiving the path switching message, the Inter-AS system 100 can check the traffic situation (for example, information load, etc.), can switch the data flow path associated with this service, and starts transmitting the data flow for the terminal through target access gateway tAG 210 rather than through the source access gateway sAG 200. Accordingly, traffic can be directly transmitted to the target access gateway tAG 210 through the Inter-AS system 100 and then immediately transmitted to the target base station "TeNB" 310, so that it can be delivered flax to the terminal through an optimized path.

[69] FIGS. 11 and 12 illustrate the forwarding procedure of an “AG” access gateway using a terminal.

[70] In FIGS. 11 and 12, the UE 410 has moved from the source base station “seNB” 300 to the target base station “teNB” 310 and receives information related to the network or system information through the target base station “teNB” 310 The information associated with the network may contain an identifier designed to identify a zone or node, etc., managed by the network. Since the terminal has moved from the network (to which it originally belonged) to another network, it is currently located in a different network, so the identifier included in the information related to the network differs from the previous identifier. After checking the identifier, the terminal transmits a message requesting for redirection (redirection) of the access gateway path “AG” to the target base station “teNB” in order to inform the network (target base station “teNB”) that it has again moved to the network and, therefore, for it needs to install a new path. When the target base station "teNB" 310 receives a request message to redirect the access gateway "AG", it transmits this message with a request to the target access gateway "tAG" 210 to inform that it is necessary to register the terminal and redirect the access gateway "AG" ".

[71] After receiving the request message forwarding the access gateway "AG", the target access gateway "tAG" 210 transmits a request for optimization of the path of the access gateway "AG" to the source access gateway "sAG" 200. After receiving the message with the request for optimization path of the access gateway "AG" from the target access gateway "tAG" 210, the source access gateway "sAG" 200 transmits a response to a message requesting optimization of the path of the access gateway "AG" to the target access gateway "tAG" 210.

[72] In Fig. 11, after receiving the message with the request for optimization of the path of the access gateway "AG" by the source access gateway "sAG" 200, it transmits a message about switching the path to the Inter-AS system 100. In Fig. 12, after receiving by the target gateway access "tAG" 210 replies to a request message for optimizing the path of the access gateway "AG" from the original access gateway "sAG" 200, it transmits a message about switching the path to the system "Inter-AS" 100.

[73] As already described, when the mobile terminal 410 is connected to the second radio network node (target base station "teNB") 310 in the same state as it was connected to the first radio network node (original base station "seNB") 300, switching to the access gateway, which is most suitable for transmitting a data stream through an optimized path, due to which network congestion and unnecessary signaling process generated in known technical solutions can be reduced.

[74] FIG. 13 illustrates an example structure of a mobile terminal in accordance with the present invention.

[75] As shown, the mobile communication terminal 500 may comprise a transceiver 550 for transmitting and / or receiving data through a data stream path in a mobile communication system over a wireless channel (Wi-Fi, Wi-MAX, Wi-bro, etc. d.) and the like; a storage device 540 for storing data transmitted or received through a transceiver or from an external source; processor 510, designed to send a request for optimization of the data flow transmission path during or after the transfer of the subscriber connection from the source “Node B” to the target “Node B” to the network, which determines the optimized data flow path, and receiving data from the network through the optimized data flow path.

[76] As you can understand, there are other components in the mobile terminal, but they are not considered in detail, so as not to complicate the understanding of the characteristics of the present invention due to excessive details.

[77] The present invention provides a method for forwarding an “AG” access gateway in a mobile communication system comprising network components and at least one terminal, comprising the following steps: sending a forwarding request from a target “Node B” (for example, a target base station “TeNB”) to the target access gateway; sending a path optimization request from the target access gateway to the source access gateway; sending a request to switch the path from at least one of the following gateways: the target access gateway or the source access gateway to the upstream system object; the establishment by an upstream object of the system of an optimized path for data transmission between the terminal and this object of a higher level; re-creating an optimized path when the information load conditions have changed significantly; sending the target "Node B" information related to the network and / or system information to the terminal, while the information associated with the network contains an identifier designed to determine the domain and / or node managed by the network; sending a request to the terminal to change or save the state of the terminal; sending a response in exchange for a request for path optimization from the source access gateway to the target access gateway; adding the terminal to the list of the target access gateway depending on the response received by the target access gateway, and / or removing the terminal from the list of the target access gateway depending on the response received by the target access gateway; wherein the forwarding request is a message requesting to redirect the access gateway "AG", the request for path optimization is a request message for optimizing the path of the access gateway "AG", and the request for switching the path is a message requesting to switch the path " AG "; at the same time, an object of a higher level (for example, a node of a higher level, the Inter-AS system) determines an optimized path depending on the state of the information load (traffic), which is determined by at least one of the following: a traffic congestion situation, The situation with user congestion and bandwidth access gateways; at the same time, at least one of the two: the source access gateway or the target access gateway - has terminal information related to at least one of: authentication information, security information, information related to compression, information about the service or location tracking information “TA”; however, these steps are performed if the terminal is in quasi-active mode; wherein the request for forwarding contains information about the terminal associated with at least one of the following: authentication information, security information, information related to compression, information about the service and location tracking information “TA”; however, the request for optimization of the path contains at least one of the following: terminal context data identifying information and security information.

[78] Furthermore, the present invention provides a method for forwarding an “AG” access gateway in a mobile communication system, comprising the following steps: determining whether forwarding of a data flow path is necessary; if this redirection is necessary, then the identification of the terminal operating mode; and sending to the terminal a request for a change of mode if the terminal is in active mode, or creating an optimized transmission path for the data stream if the terminal is in inactive mode; in which the inactive mode is at least one of the modes: quasi-active mode or standby mode.

[79] In addition, the present invention provides a terminal-based forwarding method for an “AG” access gateway in a mobile communication system, comprising the steps of: sending a request to a target “Node B” to optimize a data flow path during or after transmission a subscriber connection from the source “Node B” (base station “NB”) to the target “Node B”, to the network, which defines an optimized transmission path of the data stream; sending a request for forwarding from the target base station "NB" to the target access gateway; sending a path optimization request from the target access gateway to the source access gateway; sending a request to switch the path from at least one of the following gateways: the target access gateway or the source access gateway - to a higher-level object; and creating an object of a higher level of an optimized path for data transmission; and receiving data from the network through an optimized path; the sending step is performed if the terminal is in inactive mode; at the same time, the object of a higher level is a network node or an Inter-AS transit autonomous system.

[80] Although the present invention has been described in the context of mobile communications, it can also be used in many wireless communication systems using mobile devices, such as PDAs and laptops equipped with wireless features. In addition, the use of certain terms to describe the present invention should not limit the scope of the present invention to a certain type of wireless communication system. The present invention is also applicable to other wireless communication systems using various wireless interfaces and / or physical layers, for example, TDMA (time division multiple access), CDMA (code division multiple access), FDMA (frequency division multiple access), WCDMA (Wideband Multiple Access with Channel Separation), OFDM Orthogonal Frequency Division Multiplexing, EV-DO Mobile Internet Evolution Systems, IEEE Wi-Max, Wi-Bro and n.

[81] The exemplary embodiments may be implemented as a method, device, or finished product using standard programming and / or design methods to obtain software, firmware, hardware, or any combination thereof. The term “industrial product” as used herein refers to embedded programs or logic elements embedded in hardware logic (eg, integrated circuit, user programmable gate array (FPGA), specialized integrated circuit (ASIC), etc.) or computer media data (e.g. media with magnetic storage media (e.g. hard drives, floppy disks, tape drives, etc.), optical storage devices (compact discs (CD-ROMs), optical disks, etc.), volatile and energy readable memory devices (for example, EEPROM - electronically-programmable read-only memory), ROM (read-only memory (ROM)), PROM (programmable read-only memory (ROM)), RAM (random access memory (RAM)), DRAM (dynamic RAM), SRAM (static RAM), firmware, programmable logic, etc.

[82] Firmware on a computer-readable medium is accessible to the processor and can be executed by it. Embedded programs in which preferred embodiments of the present invention are implemented can be accessed through a transmission medium or through a network file server. In such cases, an industrial product that uses computer programs may contain a transmission medium, such as a transmission line in a network, wireless communications, propagation of signals through space, radio waves, infrared signals, etc. Of course, a person skilled in the art will recognize that many modifications can be made in this configuration without departing from the scope of the present invention, and that the industrial product may contain any storage medium known in the art.

[83] Since the present invention can be implemented in several ways, without going beyond the spirit and its essential characteristics, it should be understood that the above embodiments of the present invention are not limited to any details of the previous description, unless otherwise expressly agreed, but are limited to in the broad sense, only the scope defined by the attached claims, and therefore, changes and modifications are possible that fall into the region limited by the provisions of the formula Retenu or their equivalents defining the region corresponding to the scope of the appended claims.

Claims (25)

1. A method of forwarding a traffic transmission path in a mobile communication system containing network entities and at least one terminal, including:
sending a request for forwarding from the target “Node-B” to the target access gateway;
sending a path optimization request from the target access gateway to the source access gateway and
sending a request to the upstream object of the system for switching the path from at least one of the gateways: the target access gateway or the source access gateway. 2. The method according to claim 1, additionally containing the reception by the target “Node-B” from the terminal of the request for redirection during or after the transfer of the subscriber connection from the source “Node-B” to the target “Node-B”. 3. The method according to claim 1, further comprising establishing an upstream system object of an optimal transmission path for transmitting data between said terminal and said upstream system object. 4. The method according to claim 3, wherein said upstream system object determines an optimal transmission path based on traffic load conditions. 5. The method according to claim 4, in which traffic load conditions are determined using at least one of the following: traffic congestion situation, user congestion situation, access gateway bandwidth. 6. The method according to claim 4, further comprising re-establishing the optimal path when traffic load conditions change significantly. 7. The method according to claim 1, wherein the upstream system object is an upstream node or an Inter-AS transit autonomous system. 8. The method according to claim 1, in which the forwarding request is a request message forwarding the access gateway "AG", the request for path optimization is a message requesting path optimization for the access gateway "AG" and the path switching response is a message about switching the access gateway path "AG". 9. The method according to claim 2, in which at least one of the nodes: the source "Node-B" and the target "Node-B", is an improved "Node-B". 10. The method according to claim 2, additionally containing the direction of the target "Node-In" to the terminal information related to the network and / or system information. 11. The method of claim 10, wherein the network related information includes an identifier to determine a domain and / or node managed by the network. 12. The method according to claim 1, in which at least either the source access gateway or the target access gateway contains terminal information related to at least one of the following: authentication information, security information, compression related information, service information and location tracking information “TA”. 13. The method according to claim 1, in which these steps are performed if the terminal is in quasi-active mode. 14. The method of claim 1, further comprising sending a request to the terminal for changing or maintaining the state of the terminal. 15. The method of claim 1, wherein the forwarding request includes terminal information related to at least one of the following: authentication information, security information, compression information, service information and information tracking location "TA". 16. The method of claim 1, wherein the path optimization request includes at least one of: terminal context information identifying information, authentication information, security information. 17. The method according to claim 1, additionally containing a direction from the source access gateway to the target access gateway response to the request for optimization of the path. 18. The method according to 17, in which the response includes at least one of: authorization of authentication information and security information. 19. The method of claim 17, further comprising adding the terminal to the list of the target access gateway based on the response received by the target access gateway and / or removing the terminal from the list of the target access gateway based on the response received by the target access gateway. 20. A method for forwarding a traffic path in a mobile communication system, including:
determining if there is a need to redirect the traffic path;
determination of the operating mode of the terminal, if redirection of the traffic path is necessary; and
establishing an optimal traffic path if the terminal is in inactive mode. 21. The method according to claim 20, in which the specified inactive mode is at least one of the modes: quasi-active mode or standby mode. 22. A method for forwarding a graph path in a mobile communication system, including:
sending to the target “Node-B” a request for an optimal traffic path during or after the subscriber’s connection is transferred from the source “Node-B” (“NB”) to the target “Node-B” in a network that defines an optimized traffic path by:
sending a request for redirection from the target node "Node-B" to the target access gateway;
sending a path optimization request from the target access gateway to the source access gateway;
sending a request to switch the path from at least one of the following gateways: the target access gateway or the source access gateway, located above the system object; and
the establishment of the above-mentioned object of the system optimized path for transmitting data and receiving data from the network through this optimized traffic path. 23. The method according to item 22, in which the step of sending is performed if the terminal is in an inactive mode. 24. The method according to claim 1, wherein the upstream system object is a network node or an Inter-AS transit autonomous system. 25. A mobile terminal for transmitting and receiving data through a traffic path in a mobile communication system, comprising:
a transceiver for transmitting and / or receiving data;
a storage device designed to store data transmitted or received through the transceiver or from an external source;
a processor interacting with said transceiver and storage device and adapted to perform the following operations:
sending a request to optimize the traffic path during or after the transfer of the subscriber connection from the source “Node B” to the target “Node B” to the network, which determines the optimized path of the data stream by sending a request for redirection from the target “Node-B” to the target access gateway; sending a path optimization request from the target access gateway to the source access gateway; sending a request to switch the path from at least one of the following gateways: the target access gateway or the source access gateway, located above the system object; and the establishment of the specified upstream object of the system optimized traffic path for data transmission; and
receiving data from the network through this optimized traffic path.

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