KR20090059364A - Method, apparatus and system for allocating radio network temporary identifier - Google Patents

Abstract

A method, an apparatus and a system for allocating a radio network temporary identifier are provided to allocate absolute speed control information by using one E-AGCH. A mobile terminal transmits an RRC connection request message to a wireless network control unit(S102), and an RNC requests the setting of a wireless channel, and a base station includes the allocation information for two wireless network temporal identifiers to a response message for the wireless channel set request message(S106). The base station transmits the response message to the RNC(S108). A data transmission barrier is set up between the base station and an RNC, and a wired resource is setup between the base station and the RNC(S110). The synchronization for the wired resource is performed(S112), and a base station transmits absolute speed control information to the mobile terminals(S118).

Description

Method, apparatus and system for allocating a radio network temporary identifier {Method, apparatus and system for allocating Radio Network Temporary Identifier}

The present invention relates to the assignment of a radio network temporary identifier in a mobile communication system. More particularly, the common absolute speed control information is allocated by allocating a plurality of terminals having similar attributes to share one radio network temporary identifier. A method, apparatus and system for allocating a wireless network temporary identifier can be received.

UMTS, the third generation mobile communication system, is leading the standardization in the 3GPP (3 Generation Partnership Project), a standard developed by combining CDMA technology with European GSM. The UMTS mobile communication system is called an asynchronous mobile communication system because it does not use the Global Position System (GPS) for synchronization when compared to other 3G system CDMA 2000 systems. The UMTS system integrates a variety of systems, including cellular, wireless telephone, wireless LAN and satellite communications, and provides international roaming to make calls anywhere in the world. In addition, it supports multimedia services such as voice and image data at variable rates of up to 2Mbps, and is used in the same requirements and the same frequency band as IMT-2000, such as interworking with various broadband networks.

Recently, the wideband code division multiple access system (WCDMA), which is being actively researched and commercialized for the construction of the future high-speed packet data transmission network in the technology evolution of the 3rd generation mobile communication system, uses a conventional GSM network structure. The base station has been evolving based on the existing code division multiple access system (CDMA) of the IS-95 (Interim Standard-95) series. Not only is it advantageous in terms of infrastructure construction, it can be said that the technology market and growth potential of the future are very high. In particular, the high speed downlink package access (HSDPA) and high speed uplink packet access (HSPA) technologies are introduced to improve the efficiency of using frequency bands and processing of packet data. Improved transmission speed of uplink or downlink.

Among them, the high-speed uplink packet access technology can improve the uplink network performance, thereby enabling the rapid retransmission of incorrectly transmitted data, thereby reducing the transmission delay and adjusting the transmission speed according to the good and bad channel quality. . For such transmission output (rate) control, the high speed uplink packet access technique is based on Node-B Scheduling, Hybrid Automatic Retransmission Request (HARQ), Soft Handover, and Adaptive. It supports technologies such as Adaptive Modulation and Coding (AMC) and Short Horter Transmission Time Interval (TTI). Correspondingly, 3GPP uses a transport channel called an Enhanced Uplink Dedicated Channel (hereinafter referred to as EUDCH or E-DCH) to control the operation of the high speed uplink packet access. The E-DCH introduces new physical layer channels, E-HICH, E-RGCH, E-AGCH, E-DPCCH, and E-DPDCH, so that the complex automatic retransmission request confirmation information (ACK / NACK) and uplink scheduling information (Uplink) It is used to transmit scheduling information, control plane information, and user plane information.

Meanwhile, in the 3GPP standard, a base station transmits absolute grant control (AG) information indicating an absolute value of the maximum allowable data rate that a mobile station can transmit as a scheduling command to the mobile station. The frame structure and coding process of the enhanced absolute speed control channel (E-AGCH) is described. The frame structure of the E-AGCH will be described with reference to FIG. 1 and the coding process will be described with reference to FIG. 2.

1 is a view showing the structure of an E-AGCH frame according to the prior art. One E-AGCH radio frame having a length of 10 msec is composed of five subframes each having a length of 2 msec, each subframe is composed of three slots. It can be seen that each slot is 20 bits long and has a length of 2560 chips. Depending on the category of the mobile terminal managed by each cell, a frame of 10 ms may be used, or a subframe of 2 ms may be used auxiliary.

2 is a conceptual diagram illustrating a coding order of AGCH according to the prior art.

Referring to FIG. 2, initially input AG information includes 5 bits ( _Abv1 to X _agv5 ) of an absolute grant value indicating a maximum allowable data rate of a terminal or a power offset corresponding thereto. It can be seen that the AG valid process indicator (Absolute Grant Scope) indicating whether the AG information is valid for only one process of HARQ or valid for all HARQ processes is configured as 1 bit (X _ags1 ). As described above, the AG information consisting of 5 bits and 1 bit is used to control efficient radio resource allocation, which requires high reliability in the transmission process, and thus uses a channel encoding method for highly reliable transmission and reception of data. Channel coding plays a role of recovering an error occurring in the transmission process by adding additional information to data to be transmitted.

In detail, first, the 5-bit absolute speed control values (Xagv1 to Xagv5) and the 1-bit absolute speed grant scope (Xags1) are multiplexed to multiplex the AG information (Xag1). To Xag6) are generated (S10). The AG information is applied to an ID specific cyclic redundancy check (CRC) combiner, and the ID specific CRC combiner generates a 16-bit CRC for error detection of AG information from the AG information to be transmitted, and generates the 16-bit A 16-bit UE ID for identifying a CRC and a terminal to which the AG information is to be applied generates ID specific CRC masked with the UE ID through a modulo-2 operation performed bit by bit. Subsequently, a total of 22 bits of control information (y1, y2, ..., y22) are generated by combining with the 6 bits of AG information and then applied to the channel encoder (S20).

The channel encoder is a convolutional encoder having a constraint length of 9 and a coding rate of 1/3. After adding 8-bit tail bits to the input 22-bit control information, 1/3 A total of 90 bits ((22 + 8) * 3 = 90) of the coded bits z1, z2, ..., z90 are output to the rate matching unit by applying a coding rate of (S30). In this case, the rate matcher punctures the channel-coded 90-bit blocks z1, z2, ..., z90 or repeats the bits existing at a specific position in order to match the number of bits transmittable through AGCH. repetition) to reduce or increase the number of bits. Whether to puncture or repeatedly increase the channel-coded 90-bit block is determined in consideration of a modulation scheme and a spreading factor (SF). In FIG. 2, a puncturing scheme for a 60-bit scale is performed. 60 bits of information r1, r2, ..., r60 are applied to the physical channel mapping unit by puncturing (S40).

The physical channel mapping unit maps the 60-bit information to the E-AGCH transmitted through a 2 ms time of transmission interval (TTI) to ensure reliability (S50). Here, the rate matching pattern of the rate matching unit is preferably used by the transmitter and the receiver in the same manner by definition.

On the other hand, through the above-described Node-B Scheduling technology, the base station can adjust the transmission rate of the uplink of the mobile terminal by controlling the transmission rate of the mobile terminal existing in the signal transmission range (Cell). The base station provides relative grant information and absolute grant information through an enhanced relative rate control channel (E-RGCH) and an enhanced absolute rate control channel (E-AGCH). By controlling the rate control (Absolute Grant) information to the mobile terminal to control the transmission rate that can be used by the mobile terminal. Among them, the enhanced absolute speed control channel (E-AGCH) is a shared channel, and using the enhanced E-DCH Radio Network Temporary Identifier (E-RNTI), absolute speed control information is used. (Ie, AG information) is transmitted to a specific mobile terminal. That is, when allocating resources to the terminal through the E-AGCH, it is distinguished by using the E-RNTI set in the mobile terminal.

In this case, since two E-RNTIs are uniquely allocated to each mobile terminal, when the base station allocates resources through the E-AGCH, the corresponding E-RNTIs of each terminal must be checked and allocated individually. The problem is that it is inefficient and wastes radio resources.

SUMMARY OF THE INVENTION The present invention provides a wireless network capable of allocating common absolute speed control information using one E-AGCH by allowing a plurality of mobile terminals having similar properties to share one wireless network temporary identifier. It is to provide a method, apparatus and system for allocating a temporary identifier.

The object of the present invention is not limited to the above-mentioned object, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

In the method for allocating a radio network temporary identifier according to an embodiment of the present invention for achieving the above object, a method for allocating a radio network temporary identifier (RNTI) in a base station of a mobile communication system, for each mobile terminal Assigning a unique first radio network temporary identifier (Primary RNTI) to the radio network controller; Classifying the mobile terminal according to a predetermined attribute; And assigning to the radio network controller a second radio network temporary identifier (Secondary RNTI) shared by the mobile terminals classified with the same attribute.

In addition, a method for allocating a radio network temporary identifier according to an embodiment of the present invention for achieving the above object includes the steps of a mobile terminal transmitting an RRC connection request message to a radio network controller; Transmitting, by the wireless network controller, a radio link setup request message to a base station according to the RRC connection request message; Transmitting, by the base station, the response message to the radio network controller by including allocation information about a first radio network temporary identifier and a second radio network temporary identifier in a response message to the radio channel establishment request message; And assigning wired resources between the base station and the radio network controller by the response message, and synchronizing the wired resources.

In addition, the apparatus for allocating a radio network temporary identifier according to an embodiment of the present invention for achieving the above object is a base station apparatus of a mobile communication system which allocates a radio network temporary identifier (RNTI) to each mobile terminal. A first allocator for allocating a first wireless network temporary identifier (Primary RNTI) unique to the wireless network controller; A classification unit for identifying an attribute of the mobile terminal using information included in an RRC connection request message transmitted from the mobile terminal to the radio network controller, and classifying the mobile terminal according to the identified attribute; And a second allocator for allocating a second wireless network temporary identifier (Secondary RNTI) shared by the classified plurality of mobile terminals to the wireless network controller.

In addition, the system for allocating a radio network temporary identifier according to an embodiment of the present invention for achieving the above object, transmits a radio link setup request message according to the RRC connection request message received from the mobile terminal A wireless network controller; And a base station for transmitting the response message to the wireless network controller by including allocation information about a first wireless network temporary identifier and a second wireless network temporary identifier in a response message to the wireless channel establishment request message. Assigns a unique first wireless network temporary identifier (Primary RNTI) and a second wireless network temporary identifier (Secondary RNTI) shared by a plurality of mobile terminals classified as having similar attributes for each mobile terminal. .

Details of other embodiments are included in the detailed description and drawings for the implementation of the invention to be described later.

According to the method, apparatus, and system for allocating a wireless network temporary identifier according to the embodiment of the present invention as described above, one E-AGCH by allowing a plurality of mobile terminals having similar attributes to share one wireless network temporary identifier. By using the common absolute speed control information can be assigned, it is possible to efficiently save radio resources.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various different forms, and the present embodiments merely make the disclosure of the present invention complete, and are common in the art to which the present invention pertains. It is provided to fully inform those skilled in the art of the scope of the invention, which is to be defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

3 is a diagram illustrating a system for allocating a wireless network temporary identifier according to an embodiment of the present invention.

In general, the UMTS system is composed of a user equipment (UE), a UMTS Terrestrial Radio Access Network (UTRAN), and a core network (Core Network: CN). The radio according to an embodiment of the present invention The system for assigning network temporary identifiers may be implemented in a UMTS radio access network.

As mentioned in the background section, in the 3rd generation mobile communication system, high speed downlink package access (HSDPA) and high speed uplink packet access (HSDPA) in order to improve the use efficiency of the frequency band and the processing efficiency of packet data are improved. Speed Uplink Package Access (HSUPA) technology improves the transmission speed of uplink or downlink. Among them, 3GPP uses a transport channel called an enhanced uplink dedicated channel (hereinafter referred to as EUDCH or E-DCH) in order to control transmission power (rate) in a high speed uplink packet access technology. Accordingly, the system for assigning a radio network temporary identifier is preferably applied in a high speed uplink packet access (HSUPA) system.

The mobile terminal 100 is located in a plurality of sectors allocated to the communication area divided into sectors, and may be a terminal capable of executing a service provided by the third generation mobile communication system regardless of its name. In the embodiment of the present invention, the mobile terminal 100 serves to establish an RRC connection with the radio network controller 300 by transmitting an RRC connection request message to the radio network controller 300, which will be described later, and requesting the RRC connection establishment.

The UTRAN generally serves to ensure mobility of the mobile terminal 100 and performs handoff and radio resource management functions. In addition, the UTRAN is composed of one or more Radio Network Sub-systems (RNS), and each RNS is formed by one Radio Network Controller (RNC) 300 and the RNC 300. It is composed of one or more base stations (Node B) 200 to be managed.

The RNC 300 generally serves as an access point with the core network, and includes wired and wireless channel management, protocol matching with subscriber stations, protocol matching between base stations, soft handoff processing, core network protocol processing, and general packet radio service (GPRS). It is responsible for functions such as access, fault management and system loading. Here, GPRS is an asynchronous communication system that supports a data transmission speed of 115kbps, provides a multimedia mail, and maximizes the efficiency of a transmission line by packet data transmission.

The RNC 300 according to an embodiment of the present invention receives an RRC Connection Request message transmitted by the mobile terminal 100, and establishes a radio channel to the base station 200 using the NBAP protocol. By sending a Radio Link Setup Request message, the radio channel setup is requested.

The base station 200 is generally connected to the RNC 300 via an interface known as Iub in 3GPP, and serves to transmit a signal to the mobile terminal 100 through a down link (DL). In addition, it performs a radio access termination function with a subscriber station conforming to the 3GPP (3 Generation Partnership Project) radio access standard, and in the case of a third generation mobile communication network, performs a function of transmitting and receiving voice, video, and data traffic in a WCDMA manner. .

In FIG. 3, cells 1, 2, and 3 are controlled by the base station 200, which is a serving cell that mainly controls the transmission rate of uplink user data of the mobile terminal 100. It can be called a (serving cell). The cell 2 is configured to transmit to the mobile terminal 100 an enhanced absolute rate control channel (E-AGCH) that notifies the absolute transmission rate of uplink user data. In addition, the transmission rate of the uplink user data transmitted from the mobile terminal 100 through an Enhanced Dedicated Physical Data CHannel (E-DPDCH) based on the absolute transmission rate control information using the E-AGCH. It is configured to control.

Here, the enhanced absolute speed control channel (E-AGCH) is a shared channel, and using the enhanced E-DCH Radio Network Temporary Identifier (E-RNTI), absolute speed control information (ie, AG information) is a channel for transmitting a specific mobile terminal. That is, when allocating resources to the UE through the E-AGCH, corresponding terminals are distinguished by using the E-RNTI set in the mobile terminal. In addition, the E-DPDCH is a separate channel for transmitting a separate data signal of each mobile terminal 100.

The base station 200 according to an embodiment of the present invention receives a radio link setup request message transmitted by the above-described RNC 300 and responds to the radio link setup response. The response message is transmitted back to the RNC 300 including the allocation information for the first radio network temporary identifier and the second radio network temporary identifier. Here, the Radio Network Temporary Identifier (RNTI) is an identifier for the UE 100 in the RRC connection establishment process, and the first Primary E-RNTI is a respective mobile terminal 100. This branch is a unique E-RNTI, and the second wireless network temporary identifier (Secondary RNTI) is an E-RNTI shared by a plurality of mobile terminals classified as having similar attributes. Whether the plurality of terminals have similar attributes may be determined by analyzing an information element constituting an RRC connection request message transmitted by the mobile terminal 100 to the RNC 300. Detailed description thereof will be described later in the description of FIG. 4.

4 is a configuration diagram of a base station apparatus that is an apparatus for allocating a wireless network temporary identifier according to an embodiment of the present invention. The base station 200 includes a first allocator 210, a classifier 215, a second allocator 220, and a transmitter 230.

The first allocating unit 210 assigns a unique first radio network temporary RNTI to the radio network controller 300 for each mobile terminal 100 existing in the cell of the base station 200. do.

The classifier 215 analyzes an RRC connection request message transmitted by the mobile terminal 100 existing in the cell to the radio network controller 300 to determine an information element included in the RRC connection request message. Extract the Information Element. Then, the extracted information elements are used to grasp the attributes of each mobile terminal 100 and to classify the mobile terminals having similar attributes. The attribute in an embodiment of the present invention may include a service class and a channel state of the mobile terminal 100.

Information about the service class of the mobile terminal 100 may be known from establishment cause information among information elements included in the RRC connection request message. The Establishment Cause information shown in the 3GPP specification documents includes streaming service calls such as VOD services, background service calls such as Web services, interactive service calls such as video and voice calls, and interactive service calls such as games. It may include. Accordingly, mobile terminals having the same service class among the four service classes may be classified into mobile terminals having similar attributes.

In addition, the information on the channel state of the mobile terminal 100 can be known from CPICH RSCP information which is an information element added to the RRC connection request message. CPICH RSCP means Received Signal Code Power indicating the power reception strength of the CPICH channel. In other words, if the power of this channel is large, the mobile terminal is located in the center of the cell. If the power level is expressed from an integer 0 to a predetermined integer and grouped into several groups, the mobile terminals included in the group may be classified into mobile terminals having similar properties since all current channel states are similar. have.

On the other hand, after determining whether the service class of the mobile terminal is the same, it is possible to determine whether the channel state of the mobile terminal is similar, or vice versa. In addition, the mobile terminal may be classified into mobile terminals having similar attributes only when both of the above two conditions are satisfied as well as when both conditions are satisfied.

As described above, the second allocator 220 assigns a second radio network temporary identifier (Secondary RNTI) shared by a plurality of mobile terminals classified as having similar attributes to the radio network controller 300.

Information about the first and second wireless network temporary identifiers allocated by the first allocator 210 and the second allocator 220 is transmitted from the wireless network controller 300 to the mobile terminal 100 again. The transmitter 230 transmits absolute speed control information (AG information) to a plurality of mobile terminals sharing the second wireless network temporary identifier through a common absolute speed control channel (AGCH).

Hereinafter, how the allocation process of the radio network temporary identifier in the base station 200 is performed in the process of establishing the RRC connection between the mobile terminal 100 and the RNC 300 will be described with reference to FIGS. 5 to 7.

5 is a call flow diagram of an RRC connection establishment process including an allocation process of a radio network temporary identifier according to an embodiment of the present invention.

First, the UE 100 requests a connection establishment by transmitting an RRC connection request message to a radio network controller (RNC) 300 (S102). Receiving the RRC connection request message, the RNC 300 requests radio channel setting by transmitting a radio link setup request message to a Node-B 200 using an NBAP protocol (S104). ).

The base station 200 includes two radio network temporary identifiers (E-RNTIs), namely, a first radio network temporary identifier and a second radio network temporary identifier, in response to the radio channel establishment request message received from the RNC 300. The allocation information is included (S106). In this case, the base station 200 may first assign a unique first wireless network temporary identifier (Primary RNTI) for each mobile terminal, and then allocate a second wireless network temporary identifier. It is also possible to assign the identifier and the second wireless network temporary identifier at the same time.

Here, the second wireless network temporary identifier is an E-RNTI shared by a plurality of mobile terminals having similar attributes. In order to allocate the second wireless network temporary identifier, first, mobile terminals existing in a cell are classified according to their attributes. The process must be preceded. In other words, the classification unit 215 of the base station 200 parses an RRC connection request message transmitted from the mobile terminal 100 to the RNC 300 in step S102 to determine from the information included in the RRC connection request message. The attributes of the mobile terminals are identified, and the mobile terminals are classified according to the identified attributes. A process of classifying mobile terminals according to the attribute will be described in detail with reference to FIG. 6.

6 is a diagram illustrating a process of classifying mobile terminals according to attributes of the mobile terminal according to an embodiment of the present invention.

First, the first allocating unit 210 of the base station 200 allocates a unique first radio network temporary identifier to the RNC 300 for each mobile terminal existing in its cell (S202).

The classifier 215 determines whether the service classes of the mobile terminals existing in the cell are the same (S204). The information about the service class may be known from establishment cause information among information elements included in the RRC connection request message as described above. The establishment cause information may include a streaming service call such as a VOD service, a background service call such as a web service, an interactive service call such as a video / voice call, and an interactive service call such as a game. . Accordingly, mobile terminals having the same service class among these four service classes may be classified into mobile terminals having similar attributes. However, even if the service class is determined to be the same, if the channel states are not similar, it may be inefficient to allocate the E-RNTI in common.

Therefore, when the classifier 215 determines that the service classes are the same in step S204 (YES in S204), the classification unit 215 determines whether the channel states of the mobile terminals existing in the cell are similar (S206). As described above, the channel state information may be known from CPICH RSCP information which is an information element added to the RRC connection request message. CPICH RSCP means Received Signal Code Power indicating power reception strength of the CPICH channel. In other words, if the power of this channel is large, the mobile terminal is located in the center of the cell. If the power level is expressed from an integer 0 to a predetermined integer and grouped into several groups, the mobile terminals included in the group may be classified into mobile terminals having similar properties since all current channel states are similar. have.

An embodiment of a classification process of mobile terminals according to the above attributes is shown in FIG. 7. In FIG. 7, if service classes of UE1, UE3, and UE4 are the same, and channel states of UE1 and UE3 are similar, UE1 and UE3 satisfying both conditions may be classified as mobile terminals having similar attributes. Will be assigned a common second wireless network temporary identifier.

As such, the second allocator 220 sets the second wireless network temporary identifier shared by the plurality of mobile terminals classified as having similar attributes to the RNC 300 by setting it as the shared E-RNTI (S207). Then, the transmitter 230 transmits absolute speed control information (AG information) to a plurality of mobile terminals sharing the second wireless network temporary identifier through a common absolute speed control channel (E-AGCH). (S209).

If it is determined in step S204 that the class of service is not the same or the channel state is not similar in step S206 (NO in step S204 and S206), the second wireless network temporary identifier is shared by the legacy method. And assigns it to the RNC 300 (S208), and then the transmitter 230 transmits absolute speed control information (AG information) to each mobile terminal individually through an absolute speed control channel (E-AGCH) (S210). ).

On the other hand, as in the above-described process S204 and S206 of FIG. 6, after determining whether the service class of the mobile terminal is the same, it may be determined whether the channel states of the mobile terminal are similar, but also in the reverse order. It is possible. In addition, although the above two conditions must be satisfied in parallel, the mobile station having similar attributes can be classified and allocated to the second wireless network temporary identifier in common, but only one of the two conditions is satisfied according to the operator's judgment. In this case, the mobile terminal may be classified into mobile terminals having similar attributes.

Returning to the description of FIG. 5 again, the base station 200 transmits a response message including the allocation information for the first radio network temporary identifier and the second radio network temporary identifier to the RNC 300 (S108). . Thus, the Iub data transmission bearer is established between the base station 200 and the RNC 300 by the transmission of the response message, and wired resources are allocated to each other (S110). In addition, the synchronization for the wired resource (Synchronization) is performed both up and down (S112).

After performing the synchronization, the RNC 300 includes the information on the first and second radio network temporary identifiers in the response message for the RRC connection request message received in step S102 (S114), and moves the response message. It transmits to the terminal (S116). Through this process, the mobile terminal 100 can check information about the first wireless network temporary identifier uniquely assigned to the mobile terminal and the second wireless network temporary identifier assigned in common. In addition, the mobile terminal 100 notifies that the RRC connection setup is completed by transmitting an RRC connection setup complete message to the RNC 300.

The base station 200 transmits absolute speed control information to a plurality of mobile terminals classified as having similar attributes through a common absolute speed control channel (S118).

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features thereof. I can understand that. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive.

1 is a view showing the structure of an AGCH frame according to the prior art.

2 is a conceptual diagram illustrating a coding order of AGCH according to the prior art.

3 is a diagram illustrating a system for allocating a wireless network temporary identifier according to an embodiment of the present invention.

4 is a configuration diagram of a base station apparatus that is an apparatus for allocating a wireless network temporary identifier according to an embodiment of the present invention.

5 is a call flow diagram of an RRC connection establishment process including an allocation process of a radio network temporary identifier according to an embodiment of the present invention.

6 is a diagram illustrating a process of classifying mobile terminals according to attributes of the mobile terminal according to an embodiment of the present invention.

7 is an exemplary diagram of classifying attributes of mobile terminals according to an embodiment of the present invention.

(Description of the main parts of the drawing)

100: mobile terminal 200: base station

210: first allocation unit 215: classification unit

220: second allocation unit 230: transmission unit

300: wireless network controller

Claims (14)

A method of allocating a radio network temporary identifier (RNTI) at a base station of a mobile communication system, Assigning a first wireless network temporary identifier (Primary RNTI) unique to each mobile terminal to the wireless network controller; Classifying the mobile terminal according to a predetermined attribute; And Allocating a second wireless network temporary identifier (Secondary RNTI) shared by a mobile terminal classified with the same attribute to the wireless network controller. The method of claim 1, Classifying the mobile terminal, Determining a property of the mobile terminal by using information included in an RRC connection request message transmitted from the mobile terminal to the wireless network controller. The method of claim 2, The attribute of the mobile terminal, And whether the service class of the mobile terminal is the same, or whether the channel state of the mobile terminal is similar. The method of claim 3, wherein The service class is And at least one of a streaming service call, a background service call, an interactive service call, and an interactive service call. The method of claim 3, wherein The channel state is A method for allocating a radio network temporary identifier as determined according to a magnitude of a received signal code power (RSCP) indicating a power reception strength of a CPICH channel. The method of claim 1, Transmitting information about the assigned first and second radio network temporary identifiers from the radio network controller to the mobile terminal; And And transmitting absolute speed control information through a common absolute speed control channel (AGCH) to the plurality of mobile terminals sharing the transmitted second wireless network temporary identifier. . The method of claim 1, The mobile communication system, A method of assigning a wireless network temporary identifier, which is a high speed uplink packet access (HSUPA) system. The mobile terminal transmitting an RRC connection request message to the radio network controller; Transmitting, by the radio network controller, a radio link setup request message to a base station according to the RRC connection request message; Transmitting, by the base station, the response message to the radio network controller by including allocation information about a first radio network temporary identifier and a second radio network temporary identifier in a response message to the radio channel establishment request message; And And assigning wired resources between the base station and the wireless network controller by the response message, and performing synchronization on the wired resources. A base station apparatus of a mobile communication system for assigning a radio network temporary identifier (RNTI), A first allocator for allocating a first wireless network temporary identifier (Primary RNTI) unique to each mobile terminal to the wireless network controller; A classification unit for identifying an attribute of the mobile terminal using information included in an RRC connection request message transmitted from the mobile terminal to the radio network controller, and classifying the mobile terminal according to the identified attribute; And And a second allocator for allocating a second wireless network temporary identifier (Secondary RNTI) shared by the classified plurality of mobile terminals to the wireless network controller. The method of claim 9, The classification unit, And classifying the mobile terminal according to whether the service class of the mobile terminal is the same and whether the channel state of the mobile terminal is similar. The method of claim 10, The channel state is A device for allocating a radio network temporary identifier, which is determined according to a magnitude of a received signal code power (RSCP) indicating a power reception strength of a CPICH channel. The method of claim 9, When information about the assigned first and second wireless network temporary identifiers is transmitted from the wireless network controller to the mobile terminal, it is common to the plurality of mobile terminals sharing the transmitted second wireless network temporary identifiers. And a transmitter for transmitting absolute speed control information through an absolute speed control channel of the apparatus. A radio network controller transmitting a radio link setup request message according to an RRC connection request message received from a mobile terminal; A base station for transmitting the response message to the wireless network controller by including allocation information about a first wireless network temporary identifier and a second wireless network temporary identifier in a response message to the wireless channel establishment request message, The base station, Assigns a unique first RNTI and a second RNTI shared by a plurality of mobile terminals classified as having similar attributes for each mobile terminal, System of assignment of network temporary identifiers. The method of claim 13, The base station, Determining whether a service class of the mobile terminal is the same and whether a channel state of the mobile terminal is similar by using information included in an RRC connection request message transmitted from the mobile terminal to the wireless network controller. System of assignment of network temporary identifiers.

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