KR100856262B1 - Method for transmitting/receiving serving high speed-shared common control channel in communication system using high speed downlink packet access scheme - Google Patents

Abstract

The present invention provides a fast forward common channel that spreads and transmits user data corresponding to first channelization code information that is shared by a plurality of user terminals and assigned to each of the plurality of user terminals. Transmitting reset information of serving high speed common control channel set information in a mobile communication system having a plurality of high speed common control channels for transmitting control information including at least the first channelization code information for the corresponding user terminals to receive; Is assigned a plurality of second channelization codes for spreading the fast common control channel to each of the plurality of fast common control channels, and a plurality of second channelization codes assigned to each of the plurality of fast common control channels. Multiple serving highs by correlating one of them with the high speed common control channel. Generating common control channel sets, assigning one serving high speed common control channel set of the plurality of serving high speed common control channel sets to each of the user terminals, and assigning the serving high speed common control to each of the user terminals A process of managing a state of assigning a channel set and a new serving high speed common to be allocated to the specific user terminal when detecting that the serving high speed common control channel set allocated to the specific user terminal needs to be changed while managing the state Allocating a control channel set, transmitting a message indicating that a serving high speed common control channel set is changed to the specific user terminal, and transmitting data to the new serving high speed common control channel from a specific time point after transmitting the message. It includes the process of doing.

Serving high speed common control channel set information, NBAP message

Description

{METHOD FOR TRANSMITTING / RECEIVING SERVING HIGH SPEED-SHARED COMMON CONTROL CHANNEL IN COMMUNICATION SYSTEM USING HIGH SPEED DOWNLINK PACKET ACCESS SCHEME}

1 is a diagram illustrating a general structure of a general UMTS communication system

2 is a diagram illustrating a forward channel structure of a communication system using a fast forward packet access scheme;

3 illustrates a second dedicated physical channel structure of a communication system using a fast forward packet access scheme;

4 is a diagram schematically illustrating a service performing process in a communication system using a fast forward packet access scheme;

5 is a signal flow diagram illustrating a process of transmitting user data to a UE in a CELL_DCH state in a communication system using a fast forward packet access scheme;

6 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a first embodiment of the present invention.                 

7 illustrates an operation of a base station according to the first embodiment of the present invention.

8 is a flowchart showing the operation of a base station controller according to the first embodiment of the present invention.

9 is a flowchart illustrating UE operation according to the first embodiment of the present invention.

FIG. 10 illustrates a structure of a fast common control channel transmitter for performing a function in the first embodiment of the present invention. FIG.

FIG. 11 illustrates a structure of a fast common control channel receiver for performing a function in the first embodiment of the present invention. FIG.

12 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a second embodiment of the present invention.

13 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a second embodiment of the present invention.

14 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a third embodiment of the present invention.

15 illustrates an operation of a base station according to a third embodiment of the present invention.

16 is a flowchart illustrating operation of a base station controller according to a third embodiment of the present invention.

The present invention relates to a fast forward packet access communication system, and more particularly, to a method for notifying a terminal of a change in a fast shared control channel allocated to each terminal.

In general, high speed packet access (hSDPA) is a high-speed packet data to a terminal through a downlink high speed downlink shared channel (HS-DSCH) in a UMTS system. A method of configuring a related control channel and a series of methods for operating the same in order to transmit a generic name.

In order to support high-speed packet transmission in the HSDPA, the following three schemes are newly introduced.

First, Adaptive Modulation and Coding (AMC) determines the modulation scheme and coding scheme of the data channel according to the channel state between the cell and the user. Increase it. The combination of the modulation scheme and the coding scheme is called a modulation and coding scheme (MCS) and may define a plurality of MCSs from level 1 to level n. The AMC means a method of adaptively determining the level of the MCS according to a channel state between a user and a cell, thereby increasing the overall use efficiency.

Second, the n-channel stop and wait hybrid automatic retransmission request (n-channel SAW HARQ) scheme is described as follows. In the conventional ARQ scheme, an acknowledgment signal (ACK) and a retransmission packet are exchanged between a user terminal and a RNC. However, in the HSDPA, an ACK and a retransmission packet are exchanged between the user equipment and the MAC HS-DSCH of the base station Node B. Also, by configuring n logical channels, it is possible to transmit several packets without receiving ACK. In the conventional Stop and Wait ARQ scheme, the next packet can be transmitted only after receiving the ACK of the previous packet. This method has a disadvantage in that it is possible to wait for an ACK despite being able to transmit a packet. In n-channel SAW HARQ, a plurality of packets can be continuously transmitted without receiving an ACK, thereby improving channel utilization efficiency. If n logical channels are set between the user terminal and the base station, and the channels are identified by a specific time or explicit channel number, the receiving user terminal knows which channel the packet received at any point in time is. And reconstruct packets in the order in which they must be received.

Third, the fast cell selection (FCS) will be described as follows. When the user terminal using the HSDPA enters the soft handover region, the packet is transmitted only from the cell maintaining the best channel state to reduce the overall interference. In addition, when the cell providing the best channel condition is changed, the packet is transmitted using the HS-DSCH of the cell, and the transmission disconnection time is reduced as much as possible.

1 is a diagram illustrating a general structure of a general UMTS communication system.

The UMTS communication system uses the terms Core Network (100) and a plurality of Radio Network Subsystems (RNS) (hereinafter, referred to as "RNS"-110, 120) and a UE (hereinafter, referred to as a terminal or user). To use-130). The RNS 110 and the RNS 120 are composed of a Radio Network Controller (hereinafter referred to as "RNC") and a plurality of base stations (hereafter, the term B or cell is used interchangeably). . For example, the RNS 110 includes an RNC 111 and a plurality of base stations 113 and 115. The RNC is called Serving RNC (hereinafter referred to as "SRNC"), Drift RNC (hereinafter referred to as "DRNC"), or Controlling RNC (hereinafter referred to as "CRNC") depending on its role. SRNC and DRNC are names classified according to the role of each terminal. The RNC that manages the information of each terminal and is responsible for data transmission with the core network is called the SRNC of the terminal, and the data of the terminal is not the SRNC. When the RNC is transmitted and received through the SRNC, the RNC is called a DRNC of the terminal. The CRNC refers to the RNC controlling each Node B as the CRNC of each Node B. For example, if the RNC 111 manages the information of the UE 130, the RNC 111 becomes an SRNC, and the UE 130 moves so that the data of the UE 130 is the RNC 121. The RNC 121 becomes a DRNC when transmitted and received through the Rx121. The RNC 111 controlling the base station 113 becomes the CRNC of the base station 113.

HSDPA channel structure

In order to support the HSDPA service, channels created between Node B and UE are classified into forward and reverse directions as follows.

First, the associated forward dedicated channel (hereinafter referred to as Associated DPCH), high speed-shared control channel (hereinafter referred to as HS-SCCH), and high speed forward common channel (hereinafter referred to as HS-PDSCH: There is a High Speed-Physical Downlink Shared Channel, and a reverse channel includes a secondary dedicated physical channel (hereinafter referred to as a secondary DPCH).

2 is a diagram illustrating a forward channel structure of a communication system using a fast forward packet access scheme.

The Associated DPCH is composed of a field defined for supporting an existing Release-99 voice service and an HS-DSCH indicator (hereinafter, referred to as HI) indicating a presence or absence of an HSDPA packet to be received to the UE. In general, when a packet exists to be transmitted to the UE and the Node B decides to transmit the packet to the UE, the HI field is used to inform the UE to read a specific HS-SCCH. In general, when the HSDPA data packet is transmitted in units of 3 slots (that is, HSDPA 1 TTI = 3 slots), the HS-DSCH indicator is transmitted in any one slot. If there is no data to be transmitted to the UE or if there is data to be transmitted to the UE due to the determination of the Node B, the HI region is discontinuous transmission (DTX) when no data is transmitted to the UE during the corresponding TTI.

The shared control channel (hereinafter referred to as SHCCH) transmits information for controlling the following HS-DSCH channel (hereinafter referred to as HS-DSCH control information) to the UE.

1) TFRI (Transport Format and Resource related Information): Informs the modulation and channel coding method and HS-DSCH channelization code information to be used in the HS-DSCH channel.

2) HARQ information

HARQ process number: n-channel When SAW HARQ is used, it indicates a channel to which a specific packet belongs among logical channels for HARQ.

HARQ Packet Number: When the optimal cell is changed in the FCS, the UE informs the terminal of the downlink data packet number so that the UE can inform the newly selected optimal cell of the HSDPA data transmission status.

TBS size: tells the size of the data to be transmitted.

Redundancy Version: This value is used to identify retransmitted data when IR (incremental redundancy) is used among HARQ schemes, and thus a detailed description thereof will be omitted.

3) Cyclic Redundancy Check I (CRC I): A CRC value generated from the TFRI and the UE ID (hereinafter, referred to as ID). The UE ID serves as a identifier of a UE that should receive the corresponding HS-SCCH. Therefore, the CRC I is used not only for detecting an error of the HS-SCCH channel but also for checking whether the terminal decodes the HS-SCCH allocated to the terminal.

4) CRC II: CRC value generated from the value of the HARQ region included in the HS-SCCH.

In this case, one or more channelization codes may be allocated to the HS-SCCH. As shown in FIG. 2, up to four HS-SCCH channels can be allocated to each UE. Therefore, the HI of the Associated DPCH can inform the HS-SCCH channel that the UE should receive along with the presence or absence of the HSDPA data packet to be received. Since the number of SHCCH channels is possible up to 4, two bits of HI may inform the HS-SCCH channel to be received by the UE. For example, if HI is 00, the UE receives SHCCH # 0, 01 receives SHCCH # 1, 10 receives SHCCH # 2, and 11 receives SHCCH # 3. Finally, the HS-DSCH is a channel through which a data packet transmitted from a base station to a terminal is transmitted.

The set of HS-SCCH channels allocated to each UE is called an HS-SCCH set. There may be several such HS-SCCH sets in any cell, each HS-SCCH set may share the same code, and the maximum number of HS-SCCH channels included in each HS-SCCH set is four. Among the HS-SCCH sets, the HS-SCCH set allocated to a specific UE is called a serving HS-SCCH set.

Control information to be transmitted in the reverse direction to support HSDPA is as follows. First, in the HSDPA, the user terminal checks whether the data transmitted by the base station is in error and transmits the result in an acknowledgment signal (ACK) or a negative acknowledgment signal (NACK). In general, in the SAW ARQ method, ACK or NACK can be represented by 1 bit, and since HSDPA uses the n-channel SAW ARQ method, only 1 bit is allocated to the ACK / NACK signal. In the present invention, information indicating whether or not the transmitted data is error is called ACK / NACK. And the user terminal should report the channel quality to the base station. The base station receives the channel information, determines the MCS level of the HS-DSCH channel according to the channel quality, and generates a TFRI, which is an HS-DSCH transmission type. For example, if the base station reports and receives the channel quality, the channel can be in good condition, such as 16-QAM (Qaudrature Amplitude Modulation). Select the modulation method, such as Quadrature Phase Shift Keying. In the present invention, the channel quality to be transmitted to the base station by the terminal is called a CQI (Channel Quality Indicator). The method of generating the CQI by the terminal and the method of coding the CQI and ACK / NACK information are not included in the description because they are not related to the method proposed by the present invention.

3 is a diagram illustrating a second dedicated physical channel structure of a communication system using a fast forward packet access scheme.

One TTI of the secondary DPCH is 3 slots, and ACK / NACK information is transmitted in one slot, and CQI information is transmitted in the other two slots. In FIG. 3, the ACK / NACK is transmitted to the first slot of the TTI. However, the slot in which the ACK / NACK is transmitted may be variable. In the example of FIG. 3, an example in which both values of the ACK / NACK region and the CQI region exist is present, but values of the two regions may not coexist depending on circumstances. This is the case when the period of transmitting the CQI does not coincide with the time of transmitting ACK / NACK. In this case, the CQI or ACK / NACK region not transmitted is DTX.

4 is a diagram schematically illustrating a service performing process in a communication system using a fast forward packet access scheme.

First, the UE measures the channel quality between itself and the Node B and transmits the result in the CQI region. The specific method of measuring the channel quality is irrelevant to the present invention. Node B performs scheduling using the CQI information transmitted from the UE. Scheduling refers to an operation of determining a UE to receive data in a next TTI among a plurality of UEs receiving HSDPA service in the same cell, and determining a modulation scheme to be used for the data transmission and the number of codes to be allocated. When data transmission for a certain UE is determined, the Node B transmits HI through an Associated DPCH established with the UE. As described above, HI plays a role of identifier of HS-SCCH that data will be transmitted to the corresponding UE through HS-PDSCH and control information necessary for receiving the data. The UE recovers the data after obtaining all the information on how to recover the data included in the HS-PDSCH from the TFRI information included in the HS-SCCH. Subsequently, the UE informs Node B whether or not to receive the corresponding data after a predetermined time using the ACK / NACK region.

Cell-level configuration In order for the HSDPA service scenario to be possible, each cell must have information related to HS-PDSCH and information related to HS-SCCH. Since the RNC managing each cell allocates and changes radio resources to be used in each cell, the RNC determines a resource to be used for the HS-PDSCH and the HS-SCCH for each cell and informs the cell. For this purpose, Cell Setup or Cell Reconfiguration procedure can be used among the signaling procedures defined in the current standard. In this case, information related to HS-PDSCH and HS-SCCH to be used in each cell should be included to support HSDAP service. Another possibility is to define a new procedure to inform the cell of this information. Examples of HS-PDSCH and HS-SCCH related information that the RNC informs each cell include total power to be used for HS-PDSCH transmission, OVSF code information to be used for HS-PDSCH, and code information to be used for HS-SCCH.

HSDPA Service Startup Scenario

In the situation where each cell configures the HS-PDSCH and the HS-SCCH necessary for the HSDPA service through the above procedure, a process of receiving data using an HSDPA by a UE is as follows. For convenience of description, any UE is in a CELL_DCH state, and the generated channels are defined as channels that do not assume HSDPA service. The fact that the UE is in the CELL_DCH state indicates that a dedicated channel for voice or multimedia data transmission is established between any UE and the RNC.

5 is a signal flow diagram illustrating a process of transmitting user data to a UE in a CELL_DCH state in a communication system using a fast forward packet access scheme.

In step 501, the SRNC determines that the HS-DSCH should be generated to support the HSDPA service and transmits a RADIO LINK RECONFIGURATION PREPARE message. Subsequently, in step 502, the DRNC transmits a RADIO LINK RECONFIGURATION PREPAER message to generate a RL synchronized to the corresponding Node B. The RADIO LINK RECONFIGURATION PREPARE message may transmit HS-DSCH related information, UE related information, and HARQ related information. The HS-DSCH-related information includes MAC-d PDU size, scheduling priority, HS-SCCH power offset, etc. The UE-related information includes the number of codes that a UE can decode simultaneously in one slot. In addition, the HARQ-related information includes the number of HARQ processes. In step 503, Node B generates channels related to HS-DSCH and informs DRNC of the generated channels using the RADIO LINK RECONFIGURATION READY message. Information included in this case informs the generated HS-DSCH-related information, information on the HS-SCCH set, and information on a serving HS-SCCH set allocated to the UE among the HS-SCCH sets. In step 504, the DRNC sends a RADIO LINK RECONFIGURATION READY message to the SRNC. In step 505, the SRNC commands generation of a channel related to HS-DSCH through a RADIO LINK RECONFIGURATION COMMIT message. In step 506, the DRNC commands generation of a related channel by sending a RADIO LINK RECONFIGURATION COMMIT message to the corresponding Node B. In step 507, the SRNC informs the UE of the information on the HS-DSCH-related channel using a RADIO BEARER RECONFIGURATION message. The HS-DSCH-related information included in this case may be HS-DSCH-related information included in step 503. In step 508, the UE informs the SRNC of the reception of the HS-DSCH related information using a RADIO BEARER RECONFIGURATION COMPLETE message. After this step, the UE and the Node B share relevant channels to be used for HSDPA service.

When the SRNC receives data to be transmitted to the UE in step 509, the SRNC transmits an HS-DSCHCAPACITY REQUEST frame protocol to the D (C) RNC to inform the UE that data to be transmitted has been generated. D (C) RNC transmits this to the corresponding Node B. In step 511, the Node B determines the amount of data that can be transmitted on the HS-DSCH and informs the DRNC. At this time, a possible frame protocol may be used as the HS-DSCH CAPACITY ALLOCATION frame protocol. Subsequently, the DRNC sends the HS-DSCH CAPACITY ALLOCATION frame protocol to the SRNC. In step 513, the SRNC transmits data to Node B to be transmitted to the UE. In step 514, the Node B determines a time point to transmit data to the UE through scheduling, and then transmits HI at the time point. In step 515, the Node B transmits control information related to HS-PDSCH to the UE through the HS-SCCH, and then transmits data to the UE using the HS-PDSCH in step 516.

Referring to the above-described HSDPA service provision scenario, the RNC determines information such as an OVSF code to be used for a channel required for each cell to provide HSDPA service, and accordingly, Node B forms an HS-SCCH set. In addition, when the RNC decides to transmit data to the UE by using the HSDPA service to the specific UE, the Node B informs Node B of the information related to the HS-SCCH set and the serving HS-SCCH set, which are generated by the RNC. To tell. This is because the RNC manages radio resources such as the OVSF code assigned to Node B, but the role of Node B is to create an HS-SCCH set using the allocated OVSF code and assign it to UE according to the situation. .

However, the HSDPA service providing scenario is well applied at the time when the HSDPA service is started, but it is difficult to apply when changing the serving HS-SCCH set allocated to the UE in the situation where the HSDPA service is provided. That is, the entity deciding that the serving HS-SCCH set needs to be changed is Node B, whereas the information related to the serving HS-SCCH set may be known to the RNC only in the process of transmitting a response to the RADIO LINK RECONFIGURATION PREPARE message transmitted by the RNC. The present invention provides a method for informing the UE of the Node B through the RNC when it wants to change the serving HS-SCCH set allocated to a specific UE.                         

Here, the Serving HS-SCCH set may be variably set according to the situation of UEs receiving a HSDPA service from a base station. For example, if the number of UEs receiving HSDPA service in one base station increases, new OVSF codes may be allocated to the HS-SCCH, and the serving HS-SCCH of UEs may be allocated by assigning the new OVSF codes to the HS-SCCH. will reset the set. Since Node B can determine whether the serving HS-SCCH set needs to be reset, Node B should start the reset process. However, since the message transmitted by Node B is not defined in the signaling standard between the currently defined Node B and the RNC, that is, the Node B Application Part (NBAP), the retransmission process cannot be performed. There is a problem.

Accordingly, the present invention provides a method for efficiently transmitting serving high speed common control channel set information in a communication system using a high speed forward packet access scheme.

The present invention provides a method for directly transmitting and receiving serving high speed common control channel set information between a base station and a user terminal in a communication system using a fast forward packet access scheme.

The present invention provides a method for resetting serving high speed common control channel set information in a communication system using a high speed forward packet access scheme.

The present invention provides a method for directly resetting serving high speed common control channel set information between a base station and a user terminal in a communication system using a fast forward packet access scheme.

The present invention provides a method for resetting a serving fast common control channel set information for efficiently managing channelization code resources allocated to fast common control channels in a communication system using a fast forward packet access scheme.

The present invention provides a fast forward common channel that spreads and transmits user data corresponding to first channelization code information that is shared by a plurality of user terminals and assigned to each of the plurality of user terminals. Transmitting reset information of serving high speed common control channel set information in a mobile communication system having a plurality of high speed common control channels for transmitting control information including at least the first channelization code information for the corresponding user terminals to receive; Is assigned a plurality of second channelization codes for spreading the fast common control channel to each of the plurality of fast common control channels, and a plurality of second channelization codes assigned to each of the plurality of fast common control channels. Multiple serving highs by correlating one of them with the high speed common control channel. Generating common control channel sets, assigning one serving high speed common control channel set of the plurality of serving high speed common control channel sets to each of the user terminals, and assigning the serving high speed common control to each of the user terminals A process of managing a state of assigning a channel set and a new serving high speed common to be allocated to the specific user terminal when detecting that the serving high speed common control channel set allocated to the specific user terminal needs to be changed while managing the state Allocating a control channel set, transmitting a message indicating that a serving high speed common control channel set is changed to the specific user terminal, and transmitting data to the new serving high speed common control channel from a specific time point after transmitting the message. It includes the process of doing.
The present invention also provides a method for receiving serving high speed common control channel set information in a communication system using a high speed forward packet access scheme, the method comprising: receiving a message indicating that a serving high speed common control channel set has been changed from a base station controller; Analyzing a message to analyze a serving high speed common control channel set to be newly set, a time point to which the newly set serving high speed common control channel set is actually applied, and a newly set serving high speed common control channel set to a time point to be applied Analyzing the data, and receiving the fast common control channel signal by applying the newly set serving fast common control channel set information when it is detected that the time point to be applied is reached.

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

According to the present invention, when a serving high speed common control channel set (serving HS-SCCH set, hereinafter referred to as a "serving HS-SCCH set") is reconfigured, a base station Node B may serve the serving HS- to a user terminal (UE). We propose a method of transmitting and receiving an SCCH set. When the base station transmits the serving HS-SCCH set to the UE, Node B transmits to the RNC by inserting the identifier of the new serving HS-SCCH set in a new NBAP message called PHYSICAL CHANNEL RECONFIGURATION REQUEST, and the RNC is included in the message. The identifier of the new serving HS-SCCH set is attached to an existing RRC message such as RADIO BEARER RECONFIGURATION and transmitted to the UE. In this case, the second embodiment and the third embodiment are configured according to a method of determining a time point of applying a new serving HS-SCCH set. In addition, although the first to third embodiments of the present invention propose to transmit changed serving HS-SCCH set information using an NBAP message, it is also possible to transmit using a frame protocol.

First embodiment

 The present invention is an invention for reconfiguring Serving HS-SCCH set information to a certain UE using NBAP signaling. A first embodiment will be described with reference to FIG. 6.

6 is a signal flow diagram schematically illustrating a process of transmitting serving high speed common control channel set information according to a first embodiment of the present invention.

Referring to FIG. 6, in step 401, Node B determines resetting of a new Serving HS-SCCH Set to an arbitrary UE, and applies a new serving HS-SCCH Set ID and the new Serving HS-SCCH Set to be changed accordingly. Determine an activation time to transmit a PHYSICAL CHANNEL RECONFIGURATION REQUEST message including the new serving HS-SCCH set id information and activation time information to the RNC, and when the RNC successfully receives the message, the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message is received. Transmit to Node B (402). In addition, the RNC transmits a RADIO BEARER RECONFIGURATION message or a TRANSPORT CHANNEL RECONFIGURATIO message or a PHYSICAL CHANNEL RECONFIGURATION message including the serving HS-SCCH set id and the activation time received from the Node B to the UE (403), and the UE transmits the message. Is successfully received, a RADIO BEARER RECONFIGURATION COMPLETE message or TRANSPORT CHANNEL RECONFIGURATION COMPLETE message or PHYSICAL CHANNEL RECONFIGURATION COMPLETE message is sent to the RNC (404). Detailed operations according to this will be described with reference to FIGS. 7, 8, and 9 as follows.

Next, operation of the Node B according to the first embodiment of the present invention will be described with reference to FIG. 7.

7 is a diagram illustrating the operation of a base station according to the first embodiment of the present invention.

In step 101, Node B determines whether to change the serving HS-SCCH set for a certain UE. The process may proceed as follows.

The Node B allocates a Serving HS-SCCH set to UEs of a current cell with information on HS-SCCH resources transmitted from the RNC at the same time as the HSDPA service starts, and accordingly resource utilization of the Serving HS-SCCH Set of UEs accordingly. Taking care of it. The UE and the Node B are in a state of knowing information of the HS-SCCH corresponding to each HS-SCCH Set ID. In this case, when the number of UEs receiving HSDPA service in one base station varies according to the situation and the UE is not evenly distributed in the serving HS-SCCH sets, that is, when the efficiency of the OVSF code resource of the base station is degraded, serving HS-SCCH You can change sets. The Node B may manage the serving HS-SCCH set status as shown in Table 1 below to determine the change of the serving HS-SCCH set for the UEs.

Serving HS-SCCH set ID UEID One 1,2,3,4 2 5,6,7 ... ... N 25,26,27,28,29,30

In Table 1, the HS-SCCH set status corresponds to the ID of the UE corresponding to the RADIO LINK SETUP REQUEST message when any UE starts receiving HSDPA service, that is, when Node B receives the RADIO LINK SETUP REQUEST message. It is added to the UE ID item of the serving HS-SCCH set ID item. Similarly, when the UE terminates the HSDPA service, that is, when the base station receives the RADIO LINK DELETION REQUEST message, the UE ID item for the corresponding UE is removed from the HS-SCCH set status. Eventually, the Node B serves a particular serving HS-SCCH set at a given time in consideration of resource efficiency when too many or too few UEs are used compared to the other serving HS-SCCH sets. You can change the HS-SCCH set. Management of resource utilization of the HS-SCCH Set may be managed by a method different from the above in one embodiment.

As a result of reviewing the serving HS-SCCH set state, when it is necessary to reset a new serving HS-SCCH set for a certain UE, that is, when Node B determines the change of the HS-SCCH set in step 101, The Node B determines a new serving HS-SCCH set of the UE to improve resource efficiency (102). Here, for example, if UEs belonging to Serving HS-SCCH Set ID 2 in the resource state as shown in Table 1 terminate the HSDPA service or move to another cell, Serving HS-SCCH SET ID 2 There are no UEs using the belonging HS-SCCH, and only UEs using the HS-SCCH belonging to Serving HS-SCCH SET ID N become many situations. That is, because the utilization of the HS-SCCH resources is not uniform and is unbalanced, resetting of the Serving HS-SCCH set is required again. At this time, some of the UEs belonging to the Serving HS-SCCH Set N may be reset to use the HS-SCCHs belonging to the Serving HS-SCCH SET ID 2. At this time, which UEs may be arbitrarily determined to be reconfigured to use HS-SCCHs belonging to Serving HS-SCCH SET ID 2 or may be based on a specific criterion. Accordingly, in step 102, a new Serving HS-SCCH set is determined and UEs to which it is applied are determined. In step 103, a Node B determines a time (hereinafter, referred to as an activation time) for a UE to be applied with the new Serving HS-SCCH Set ID and the new HS-SCCH Set ID determined as described above to apply the new serving HS-SCCH Set ID. (103). At this time, the time to apply the new Serving HS-SCCH set is called Activation Time. The activation time is calculated as a connection frame number (CFN). In the CFN, when the UE and the network initially establish a connection, the UE and the Node B are determined to have the same value by a predetermined formula through a system frame number (SFN) broadcasted through a broadcast channel (BCH). It is incremented by one. The Node B having determined the activation time and the id of the new serving HS-SCCH set includes PHYSICAL CHANNEL RECONFIGURATION including the information, that is, the information about the new Serving HS-SCCH Set ID and Activation Time, for transmission to the corresponding UEs. A REQUEST message is constructed (104) and sent to the RNC (105). At this time, Node B increases the current CFN value by 1 for each frame and applies the changed Serving HS-SCCH Set ID when the increased CFN value reaches the determined activation time. The PHYSICAL CHANNEL RECONFIGURATION REQUEST message configured by Node B in step 104 is an NBAP message, and the PHYSICAL CHANNEL RECONFIGURATION REQUEST message is a message newly defined for HS-SCCH Set Reconfiguration according to the present invention. The NBAP message is constructed using ASN.1 coding scheme. When transmitting a PHYSICAL CHANNEL RECONFIGURATION REQUEST message to the RNC in step 105, the Node B transmits through a dedicated channel preset for each UE. Therefore, it is not necessary to separately specify the identifier of the UE in the message. That is, the RNC receiving the PHYSICAL CHANNEL RECONFIGURATION REQUEST message is transmitted through the dedicated channel set for each determined UE even if the information on the target UE identifier to change the HS-SCCH Set is not included in the PHYSICAL CHANNEL RECONFIGURATION REQUEST message. Is to recognize the UE to apply the HS-SCCH Set to be changed. In step 106, Node B waits for a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message sent by the RNC for a predetermined time. That is, to check whether the RNC has received a PHYSICAL CHANNEL RECONFIGURATION REQUEST message sent by Node B. If the RNC receives the PHYSICAL CHANNEL RECONFIGURATION REQUEST message well, the Node B receives the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message. The PHYSICAL CHANNEL RECONFIGURATION RESPONSE message is also a newly defined message for resetting a new HS-SCCH Set. When the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message arrives, Node B applies the changed serving HS-SCCH set for the UE to the HS-SCCH Node B transmitter, determined at 102, when the activation time determined in step 103 is reached (107). . On the contrary, if the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message does not arrive during the predetermined time, the PHYSICAL CHANNEL RECONFIGURATION REQUEST message is transmitted again by performing the process again from step 103 as shown in FIG. In this regard, the predetermined time for waiting for the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message should be set smaller than the activation time to which the modified HS-SCCH Set is applied. A more detailed description of step 107 is as follows. Node B transmits the changed serving HS-SCCH set id to the code selector of the HS-SCCH Node B transmitter, and in step 107, decreases 1 for each frame elapsed from the current CFN, and finally when CFN becomes Activation Time, Instructs the code selector to change to the changed serving HS-SCCH set. The code selector changes the HS-SCCH set corresponding to the changed serving HS-SCCH set id from among the previously stored HS-SCCH set information to the serving HS-SCCH set. Then, from the Activation Time, the Node B transmits data using the newly set HS-SCCH to the UE determined to apply the new Serving HS-SCCH Set.

The operation of the code selector will be described in more detail as follows. The code selector is configured for each UE and receives and stores HS-SCCH set related information set by the MAC-hs controller. For example, information about HS-SCCH = [                     

HS-SCCH set 1 = [C (128,124) = 0, C (128,125) = 1, C (128,126) = 2, C (128,127) = 3],

HS-SCCH set 2 = [C (128,0) = 0, C (128,1) = 1, C (128, 2) = 2, C (128, 3) = 3],

HS-SCCH set 3 = [C (128,4) = 0, C (128,5) = 1, C (128,6) = 2, C (128,7) = 3],

Serving HS-SCCH set = HS-SCCH set 2]

If so, the code selector receives and stores the information from the MAC-hs controller. In addition, the HS-SCCH id transmitted by the MAC-hs controller is converted into an appropriate OVSF code and transmitted to the spreader. That is, if the MAC-hs controller decides to transmit the HS-SCCH to the UE by using the C (128,1) code, the MAC-hs controller corresponds to 1 in the HI portion of the Associated DPCH and 1 to the code selector. To pass. The code selector converts the HS-SCCH id of 1 into specific code information of C (128,1) and delivers the same to the spreader. In this case, 1 and C (128,1) correspond to each other because the serving HS-SCCH set of the UE is set to the HS-SCCH set2.

  In step 401, when Node B decides to change the serving HS-SCCH set of the UE and transmits a new serving HS-SCCH set id to the code selector, the code selector stores the value. After that, when the activation time is reached in step 107, the MAC-hs controller instructs to apply the new serving HS-SCCH set, and the code selector follows this.

 Next, an operation of the RNC for operating the first embodiment of the present invention will be described with reference to FIG. 8.                     

8 is a flowchart illustrating the operation of a base station controller according to the first embodiment of the present invention.

When the RNC receives the PHYSICAL CHANNEL RECONFIGURATION REQUEST message (201), the RNC decodes the new serving HS-SCCH set id and activation time included in the PHYSICAL CHANNEL RECONFIGURATION REQUEST message to decode the new serving HS-SCCH set id and activation time. A RADIO BEARER RECONFIGURATION message or a PHYSICAL CHANNEL RECONFIGURATION message or a TRANSPORT CHANNEL RECONFIGURATION message including information is configured and then transmitted to the UE (202). At this time, the identification of the UE to receive the message is as described above. That is, it is determined through the identifier of the dedicated channel that received the message. In addition, if the RNC wants to deliver not only the new serving HS-SCCH set id and activation time but also other information to the UE, the type of message to be transmitted may be determined accordingly. For example, if you want to newly configure Radio Bearer including RLC parameter, if you want to newly set up RADIO BEARER RECONFIGURATION message, transport channel related parameter such as TFS, send TRANSPORT CHANNEL RECONFIGURATION message or physical channel related parameter such as power control related parameter. If you want to set a new parameter, configure a PHYSICAL CHANNEL RECONFIGURATION message. If you want to deliver only the serving HS-SCCH set id and activation time, you can use the PHYSICAL CHANNEL RECONFIGURATION message. For convenience, only the RADIO BEARE RECONFIGURATION message is shown in FIG. 8.                     

Apart from the above process, if the RNC successfully receives the PHYSICAL CHANNEL RECONFIGURATION message, the RNC transmits a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message to the Node B (203).

Next, the operation of the UE according to the first embodiment of the present invention will be described with reference to FIG. 9.

9 is a flowchart illustrating UE operation according to the first embodiment of the present invention.

Referring to FIG. 9, in step 301, a UE that receives a RADIO BEARER RECONFIGURATION message, a TRANSPORT CHANNEL RECONFIGURATION message, or a PHYSICAL CHANNEL RECONFIGURATION message including the new serving HS-SCCH set id and activation time information from the RNC is a new serving HS. Decode the SCCH set id and the activation time (302). At this time, the UE inputs the current CFN value to the CFN variable (303), and increments the CFN variable by 1 every time one frame elapses (304). If the CFN variable is equal to the activation time (305), the new serving HS-SCCH set is applied to the HS-SCCH UE receiver (306). In more detail, The UE transmits the new serving HS-SCCH set id to the code conversion unit of the HS-SCCH UE receiver, and instructs the code selector to change to the new serving HS-SCCH set in step 305. The code selector changes the HS-SCCH set corresponding to the new serving HS-SCCH set id from among the previously stored HS-SCCH set information to the serving HS-SCCH set. If so, from the Activation Time, the UE receives data from the NodeB through the HS-SCCH included in the newly changed Serving HS-SCCH Set.

The operation of the code selector will be described in more detail as follows. The code selector receives and stores information related to the HS-SCCH set delivered by the RRC. For example, information about HS-SCCH = [

HS-SCCH set 1 = [C (128,124) = 0, C (128,125) = 1, C (128,126) = 2, C (128,127) = 3],

HS-SCCH set 2 = [C (128,0) = 0, C (128,1) = 1, C (128, 2) = 2, C (128, 3) = 3],

HS-SCCH set 3 = [C (128,4) = 0, C (128,5) = 1, C (128,6) = 2, C (128,7) = 3],

Serving HS-SCCH set = HS-SCCH set 2]

If so, the code selector receives the information from the RRC and stores it. At this time, the RRC receives the information from the RNC through a RADIO BEARER SETUP message. In addition, the code selector converts the HS-SCCH id delivered by the MAC-hs controller to an appropriate OVSF code and delivers the despreader. That is, when the MAC-hs controller transfers a value of 1 to the code selector based on the HI value received through the associated DPCH, the code selector converts the value of 1 into specific code information of C (128,1). In this case, 1 and C (128,1) correspond to each other because the serving HS-SCCH set of the UE is set to the HS-SCCH set2.

When the RRC of the UE receives the RADIO BEARER RECONFIGURATION message at 301 and transmits a new serving HS-SCCH set id to the code selector, the code selector stores the value. After that, when the activation time is reached in step 307, the MAC-hs controller instructs to apply the new serving HS-SCCH set, and the code selector follows this.

Apart from the above process, when the UE successfully receives the RADIO BEARER RECONFIGURATION message or the TRANSPORT CHANNEL RECONFIGURATION message or the PHYSICAL CHANNEL RECONFIGURATION message, the UE transmits the RADIO BEARER RECONFIGURATION COMPLETE message or the TRANSPORT CHANNEL RECONFIGURATION COMPLETE message or the PHYSICAL CHANNEL RECONFIGURATION COMPLETE message. (307).

That is, a response message for notifying the RNC that the RADIO BEARER RECONFIGURATION message, the TRANSPORT CHANNEL RECONFIGURATION message, or the PHYSICAL CHANNEL RECONFIGURATION message has been successfully received is transmitted.

Next, a structure of a fast common control channel transmitter for performing a function in the first embodiment of the present invention will be described with reference to FIG.

10 illustrates a structure of a fast common control channel transmitter for performing a function in the first embodiment of the present invention.

Referring to FIG. 10, first, the MAC-hs controller 1401 sends a UE identifier (UE ID) to the UE ID storage 1402, and MS information to be used for HS-PDSCH transmission to the MS information transfer unit 1403. The code info used for the HS-PDSCH is output to the code information transfer unit 1404. In addition, the HARQ channel number, the New Data Indicator, and the Redundancy Version are transmitted to the channel number transfer unit 1405, the NDI transfer unit 1406, the RV transfer unit 1407, and the TBS transfer unit 1408, respectively. The MAC-hs controller performs scheduling using CQR, ACK / NACK information of secondary DPCHs transmitted by several UEs, and buffer conditions of each UE, and accordingly, the HS-SCCH transmitter and HS-PDSCH transmitter It is a device to control. The code selector 1424 converts the HS-SCCH identifier into an actual OVSF code by using a serving HS-SCCH set ID and HS-SCCH set related information previously received from the MAC-hs controller 1401. Output to a spreader 1418. In this case, as described above, the MAC-hs controller 1401 and the code selector 1424 must include an HS-SCCH set ID and a code mapping table. Here, the code selector 1424 converts the HS-SCCH identifier into an actual OVSF code by way of example.

When the HS-SCCH set related information stored in the code selector 1424 is as follows, that is,

Information about HS-SCCH = [

HS-SCCH set 1 = [C (128,124) = 0, C (128,125) = 1, C (128,126) = 2, C (128,127) = 3],

HS-SCCH set 2 = [C (128,0) = 0, C (128,1) = 1, C (2,126) = 2, C (3,127) = 3],

HS-SCCH set 3 = [C (128,4) = 0, C (128,5) = 1, C (128,6) = 2, C (128,7) = 3],

Serving HS-SCCH set = HS-SCCH set 2]

When the HS-SCCH ID output from the MAC-hs controller 1401 is 1, the actual OVSF code to be used for spreading the HS-SCCH becomes C (128,1).

The UE ID storage unit 1402 stores a UE ID, and when a HS-SCCH corresponding to a certain UE is transmitted for a CRC 1 operation of the HS-SCCH, a UE ID corresponding to the random UE is transmitted. The data is transmitted to the CRC calculator 1409. The MS information transfer unit 1403 may transmit the MS information used for the HS-SCCH transmission output from the MAC-hs controller 1401 to the CRC calculator 1409, the CRC calculator 1410, and the multiplexer (MUX) ( 1411). In the following description of FIG. 10, the remaining transfer units, that is, the code information transfer unit 1404, the channel number transfer unit 1405, the NDI transfer unit 1406, the RV transfer unit 1407, and the TBS transfer unit 1408 serves to deliver the information output from the MAC-hs controller 1401 to components connected to each other.

The code information transfer unit 1404 outputs the code info output from the MAC-hs controller 1401 to the CRC calculator 1409, the multiplexer 1411, and the CRC calculator 1410. The CRC calculator 1409 inputs the MS information and code info outputted from the UE ID storage 1402, the MS information transfer unit 1403, and the code information transfer unit 1404 to perform a CRC operation. The CRC calculation result is output to the multiplexer 1411. Here, the CRC calculation result performed by the CRC calculator 1409 is a CRC bit transmitted through the CRC 1 field. On the other hand, the multiplexer 1411 is the CRC operation result output from the CRC operation unit 1409, that is, CRC 1, the MS information output from the MS information transfer unit 1403, and the code information transfer unit 1404 The output code info is multiplexed to correspond to the part 1 (1211) field and the CRC 1 (1213) field of the slot format of the HS-SCCH and output to the channel coding unit 1413.

The channel coding unit 1413 inputs a bit stream output from the multiplexer 1411 and performs channel coding using a predetermined channel coding scheme, and then outputs the channel coding to the rate matching unit 1414. do. Here, it is assumed that the channel coding unit 1413 uses a convolutional coding scheme as the channel coding scheme. The rate matcher 1414 receives the signal output from the channel coding unit 1413, performs rate matching, and outputs the rate matched to the multiplexer 1417.

Meanwhile, the channel number transfer unit 1405 outputs the HARQ channel number output from the MAC-hs controller 1401 to the CRC calculator 1410 and the multiplexer 1412. The NDI transfer unit 1406 outputs the NDI information output from the MAC-hs controller 1401 to the CRC calculator 1410 and the multiplexer 1412. The RV transfer unit outputs the RV information output from the MAC-hs controller 1401 to the CRC calculator 1410 and the multiplexer 1412. The TBS transfer unit 1408 outputs the TBS information output from the MAC-hs controller 1401 to the CRC calculator 1410 and the multiplexer 1412. The CRC calculation unit 1410 may include MS information output from the MS information transfer unit 1403, code info output from the code information transfer unit 1404, and an HARQ channel output from the channel number transfer unit 1405. CRC operation is performed by inputting a number, the NDI information output from the NDI transfer unit 1406, the RV information output from the RV transfer unit 1407, and the TBS information output from the TBS transfer unit 1408. The CRC calculation result is output to the multiplexer 1412. Here, the CRC calculation result performed by the CRC calculator 1410 is a CRC bit transmitted through the CRC 2 (417) field. On the other hand, the multiplexer 1412 is a CRC operation result output from the CRC operation unit 1410, that is, CRC 2, the HARQ channel number output from the channel number transfer unit 1405 and the NDI transfer unit 1406 The NDI information outputted, the RV information outputted from the RV transfer unit 1407, and the TBS information outputted from the TBS transfer unit 1408 are included in the Part 2 1215 field and the CRC 2 1217 of the slot format of the HS-SCCH. ) And multiplexed according to the < RTI ID = 0.0 >) field.

The channel coding unit 1415 receives a bit stream output from the multiplexer 1412 and performs channel coding using a predetermined channel coding scheme, and then outputs the channel coding to the rate matching unit 1416. do. Here, it is assumed that the channel coding unit 1415 uses a convolutional coding scheme as the channel coding scheme. The rate matching unit 1416 receives a signal output from the channel coding unit 1415, performs rate matching, and outputs the result to the multiplexer 1417. The multiplexer 1417 receives the signals output from the rate matcher 1414 and the rate matcher 1416, multiplexes them according to the HS-SCCH slot format, and outputs the signals to the spreader 1418.

The spreader 1418 spreads the signal output from the multiplexer 1417 to the OVSF code output from the code selector 1424 and outputs the signal to a scrambler 1418. The scrambler 1418 scrambles the signal output from the spreader 1418 with a predetermined scrambling code and outputs it to the summer 1420. The summer 1420 adds the signal output from the scrambler 1419 with other channels, that is, another channel such as the HS-PDSCH and the associated DPCH, and outputs the same to the modulator 1421. The modulator 1421 modulates the signal output from the summer 1420 in a preset modulation scheme and then outputs the modulated signal to the RF (Radio Frequency) processor 1422. The RF processor 1422 receives a signal output from the modulator 1421, RF-processes the RF band signal, and transmits the RF signal to an air through an antenna 1423.

Next, a structure of a fast common control channel receiver for performing a function in the first embodiment of the present invention will be described with reference to FIG.

11 illustrates a structure of a fast common control channel receiver for performing a function in the first embodiment of the present invention.

Referring to FIG. 11, the RF band signal received on the air through the antenna 1722 is transmitted to the RF processor 1721, and the RF processor 1721 is based on the RF band signal received from the antenna 1722. The signal is converted into a baseband signal and output to the demodulator 1720. The demodulator 1720 receives the signal output from the RF processor 1721, demodulates the demodulation scheme corresponding to the modulation scheme used by the transmitter, that is, the base station, and outputs the demodulation scheme to the de-scrambler 1725. . The descrambler 1725 de-scrambles the signal output from the demodulator 1720 with the same scrambling code used by the base station, and then outputs the descrambling signal to the de-spreader 1718. . The despreader 1718 receives the signal output from the descrambler 1725, de-spreads the same spreading code as the spreading code used by the base station, and outputs the same to the demultiplexer (DEMUX) 1717. do. Here, the despreader 1718 performs despreading with an OVSF code corresponding to the spreading code indicated by the code selector 1723. The code selector 1723 stores the information related to the HS-SCCH set transmitted through the RADIO BEARER SETUP message during the HSDPA call setup process. When the code selector 1723 receives the HI value received through the associated DPCH, the serving HS-SCCH set is transmitted. The OVSF code of the HS-SCCH corresponding to the HI is detected and transmitted to the despreader 1718. The HS-SCCH set related information is the same as the HS-SCCH set related information stored in the code selector 1424 of the HS-SCCH Node B transmitter.

The demultiplexer 1725 demultiplexes the signal output from the despreader 1718 and divides the signal into a part 1 field, a CRC 1 field, a part 2 field, and a CRC 2 field, and then the part 1 field and the CRC 1 field signal. Is output to the rate matching unit 1714, and the part 2 field and the CRC 2 field signals are output to the rate matching unit 1716. The rate matcher 1714 rate-matches the Part 1 field and the CRC 1 field signal output from the demultiplexer 1917 and outputs the rate matched signal to the channel decoder 1713. The channel decoding unit 1713 performs channel decoding on the signal output from the rate matching unit 1714 by using a channel decoding method corresponding to the channel encoding method used by the base station, and then outputs the signal to the demultiplexer 1711. . The demultiplexer 1711 inputs a signal output from the channel decoding unit 1713 to separate the part 1 field and the CRC 1 field, and outputs the part 1 field and the CRC 1 field signal to the CRC calculator 1709. The MS information of the part 1 field is output to the MS information transfer unit 1703 and the CRC calculator 1710, and the code info of the part 1 field is sent to the code information transfer unit 1704 and the CRC calculator 1710. Output The MS information transfer unit 1703 outputs the MS information output from the demultiplexer 1711 to the MAC-hs controller 1701, and the code information transfer unit 1704 outputs the demultiplexer 1711. A code info is output to the MAC-hs controller 1701. The rate matching unit 1716 rates-matches the Part 2 field and the CRC 2 field signals output from the demultiplexer 1917 and outputs the rate-matched signal to the channel decoding unit 1715. The channel decoding unit 1715 performs channel decoding on the signal output from the rate matching unit 1716 using a channel decoding method corresponding to the channel encoding method applied by the base station, and then outputs the signal to the demultiplexer 1712. The demultiplexer 1712 demultiplexes the signal output from the channel decoding unit 1715 into a part 2 field signal and a CRC2 field signal, and then divides the part 2 field and the CRC 2 field signal to the CRC operation unit 1710. The HARQ channel number of the Part 2 field signal to the channel number transfer unit 1705, the NDI information to the NDI transfer unit 1706, the RV information to the RV transfer unit 1707, and the TBS information to the TBS transfer unit. (1708). The CRC operation unit 1710 calculates a CRC 2 using the part 2 field, the CRC 2 field signal, and the code information output from the MS information and code information transfer unit 1704 output from the MS information transfer unit 1703. And outputs the CRC 2 operation result to the MAC-hs controller 1701. The channel number transfer unit 1705 outputs the HARQ channel number output from the demultiplexer 1712 to the MAC-hs controller 1701. The RV transfer unit 1707 outputs the RV information output from the demultiplexer 1712 to the MAC-hs controller 1701, and the NDI transfer unit 1706 outputs the NDI output from the demultiplexer 1712. Information is output to the MAC-hs controller 1701, and the TBS transfer unit 1708 outputs the TBS information output from the demultiplexer 1712 to the MAC-hs controller 1701.

Then the PHYSICAL CHANNEL RECONFIGURATION REQUEST message format is shown in Table 2 below.

IE / Group Name Presence Message Discriminator M Message Type M CRNC Communication Context ID M Transaction ID M New Serving HS-SCCH set ID M Activation Time M

The PHYSICAL CHANNEL RECONFIGURATION RESPONSE message format is shown in Table 3 below.

IE / Group Name Presence Message Discriminator M Message Type M Node B Communication Context ID M Transaction ID M

In the message formats shown in Tables 2 and 3, the IE / Group Name indicates the name of each information element, and the Presence indicates whether the corresponding IE is always present (M) or in some cases (O). Indicates. The following describes the IEs that compose the PHYSICAL CHANNEL RECONFIGURATION REQUEST message in more detail. The Message Discriminator is an IE that indicates whether the message is for a private connection (2) or for a public connection (1). In this message, since it relates to a dedicated connection, code it as 2. Message Type is a part that indicates the type of the message, and is used for other purposes from 0 to 49. Therefore, this message uses some other value, for example 50. The CRNC Communication Context ID is a portion in which an identifier of a transmission resource allocated to a UE associated with a corresponding message is coded. Transaction ID is used to distinguish related messages when the same procedure is simultaneously performed between the same entities, for example, when Node B a and RNC b exchange three PHYSICAL CHANNEL RECONFIGURATION REQUEST messages and three PHYSICAL CHANNEL RECONFIGURATION RESPONSE messages. Used as For example, a transaction ID of 1 may be allocated to any PHYSICAL CHANNEL RECONFIGURATION REQUEST and RESPONSE messages, and a transaction ID of 2 may be allocated to other PHYSICAL CHANNEL RECONFIGURATION REQUEST and RESPONSE messages. Therefore, in this message, appropriate value can be assigned as Transaction ID. The new serving HS-SCCH set ID is coded in the New Serving HS-SCCH set ID. At this time, an appropriate value between 1 and 16 is coded for serving HS-SCCH set ID. The activation time is coded with an appropriate value between 0 and 255.

The composition of the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message is as follows: Message Discriminator is coded as 2. Message Type is a part that indicates the type of the message, and is used for other purposes from 0 to 49. Therefore, this message uses some other value, for example 51. The Node B Communication Context ID is a portion in which an identifier of a transmission resource allocated to a UE associated with a corresponding message is coded. Transaction ID is coded with the same value as Transaction ID of PHYSICAL CHANNEL RECONFIGURATION REQUEST message.                     

And the configuration of the RADIO BEARER RECONFIGURATION message is shown in Tables 4 to 7.

A new serving HS-SCCH set ID and an activation time may be inserted into a downlink HS-PDSCH information item of the IEs.

According to the first embodiment of the present invention, for example, even if the RADIO BEARER RECONFIGURATION message and the like are not properly delivered, the UE is not ready to receive because the Node B cannot recognize this fact. Node B may apply the changed HS-SCCH Set. Therefore, the second embodiment of the present invention proposes a method in which a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message is transmitted after receiving a RADIO BEARER RECONFIGURATION COMPLETE message.

Next, a process of transmitting serving high speed common control channel set information according to the second embodiment of the present invention will be described with reference to FIG. 12.

12 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a second embodiment of the present invention.

In the message flow according to the second embodiment of the present invention, after the RNC confirms that a RADIO BEARER RECONFIGURATION message has been successfully transmitted to the UE, that is, after receiving a RADIO BEARER RECONFIGURATION COMPLETE message from the UE, the RNC sends a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message to the Node B. . This has the advantage that can be complemented to be a more reliable operation in the application of the new Serving HS-SCCH Set. Herein, operations of the Node B and the UE for operating the second embodiment of the present invention are the same as those of the first embodiment of the present invention, and thus description thereof is omitted for convenience. However, in the second embodiment of the present invention, the time that Node B presets for receiving a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message after transmitting a PHYSICAL CHANNEL RECONFIGURATION REQUEST message may vary. That is, in the case of the first embodiment of the present invention, only the time for pre-setting for receiving the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message, that is, the time for checking whether the PHYSICAL CHANNEL RECONFIGURATION REQUEST message is received by the RNC needs to be considered. However, in the second embodiment of the present invention, in addition to receiving the PHYSICAL CHANNEL RECONFIGURATION REQUEST message of the RNC, whether the RADIO BEARER RECONFIGURATION message or the TRANSPORT CHANNEL RECONFIGURATION message or the PHYSICAL CHANNEL RECONFIGURATION message of the RNC is received and the response thereto. The time should be set in consideration of whether the message has been received by the RNC. Herein, the preset time for receiving the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message in Embodiments 1 and 2 of the present invention should be smaller than the Activation Time. Herein, an operation of the RNC according to the second embodiment of the present invention will be described with reference to FIG. 13.

13 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a second embodiment of the present invention.

When the RNC receives a PHYSICAL CHANNEL RECONFIGURATION REQUEST message from the Node B (601), a RADIO BEARER RECONFIGURATION message or PHYSICAL CHANNEL including the new serving HS-SCCH set id and the activation time included in the PHYSICAL CHANNEL RECONFIGURATION REQUEST message. A RECONFIGURATION message or a TRANSPORT CHANNEL RECONFIGURATION message is configured and then transmitted to the UE (602). Thereafter, upon receiving the RADIO BEARER RECONFIGURATION COMPLETE message or the PHYSICAL CHANNEL RECONFIGURATION COMPLETE message or the TRANSPORT CHANNEL RECONFIGURATION COMPLETE message from the UE (603), the RNC sends a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message to the Node B and terminates the process (604). .

When using the second embodiment of the present invention, Node B receives a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message as a response message after confirming that the new serving HS-SCCH set id and activation time have been successfully transmitted to the UE, and thus, a new Serving HS-SCCH. It can support reliable operation in applying Set.

The configuration of the PHYSICAL CHANNEL RECONFIGURATION REQUEST message, the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message, and the RADIO BEARER RECONFIGURATION message of the second embodiment are the same as those of the first embodiment.

 Third embodiment

In the first and second embodiments of the present invention, node B determines the activation time. Unlike this, the RNC transmits a RADIO BEARER RECONFIGURATION message and the like, and the activation time should be set to a time point after the successful transmission of the RADIO BEARER RECONFIGURATION message and the like. Therefore, it is more preferable that the RNC determines the activation time. Can be. Therefore, in the third embodiment of the present invention, when the Node B delivers an activation time (hereinafter, preferred activation time) that the new serving HS-SCCH set is to be applied to the RNC, the RNC decides the actual activation time. I would like to.

Next, a process of transmitting serving high speed common control channel set information according to a third embodiment of the present invention will be described with reference to FIG. 14.                     

14 is a signal flow diagram illustrating a schematic process of transmitting serving high speed common control channel set information according to a third embodiment of the present invention.

In step 701, Node B sends a PHYSICAL CHANNEL RECONFIGURATION REQUEST message including a new serving HS-SCCH set id and preferred activation time to the RNC, and the RNC determines the activation time with reference to the preferred activation time of the message. In this case, the RNC considers the channel status of the UE or the current traffic state, and determines when the new Serving HS-SCCH Set ID information received from the Node B reaches the UE to apply the new Serving HS-SCCH Set. You can calculate it more accurately. At this time, the application time of the new Serving HS-SCCH Set calculated by the RNC is defined as T0. Here, the RNC activates a larger value between the preferred activation time, which is the time to apply the new Serving HS-SCCH Set expected in Node B, and T0, which is the time to apply the new Serving HS-SCCH Set calculated by the RNC. It can also be set. Alternatively, when not receiving preferred activation time information from the Node B, T0 calculated by the RNC may be set as an activation time. Or, depending on the situation, the preferred activation time received from Node B may be applied as the activation time. The RNC transmits a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message to the Node B including the activation time (702). In addition, the RNC transmits a RADIO BEARER RECONFIGURATION message or a TRANSPORT CHANNEL RECONFIGURATION message or a PHYSICAL CHANNEL RECONFIGURATION message to the UE including a serving HS-SCCH set id and an activation time (703), and the UE transmits the RADIO BEARER RECONFIGURATION message or a TRANSPORT CHANNEL RECONFIGURATION. Upon successful receipt of the message or PHYSICAL CHANNEL RECONFIGURATION message, a RADIO BEARER RECONFIGURATION COMPLETE message or a TRANSPORT CHANNEL RECONFIGURATION COMPLETE message or a PHYSICAL CHANNEL RECONFIGURATION COMPLETE message is sent to the RNC (704).

Next, the operation of the base station according to the third embodiment of the present invention will be described with reference to FIG. 15.

15 is a diagram illustrating the operation of a base station according to the third embodiment of the present invention.

15 illustrates the operation of Node B for operating the third embodiment of the present invention. Steps 801 and 802 are the same as the operations of steps 101 and 102, and thus description thereof is omitted here for convenience. In step 803, Node B determines the preferred activation time. Preferred activation time determination process is the same as 103 activation time determination process. That is, in determining the preferred activation time, Node B determines the preferred activation time in consideration of the delay time after the new serving HS-SCCH set id is expected to be delivered to the UE. Can be calculated with

Preferred activation time = UL_Iub_delay + DL_Iub_delay + RNC_processing_delay + Uu_delay + UE_processing delay + Margin

In Equation 1, UL_Iub_delay is the time required for the PHYSICAL CHANNEL RECONFIGURATION message to be transmitted from the Node B to the RNC, DL_Iub_delay is the time required for the RADIO BEARER RECONFIGURATION message to be transmitted from the RNC to the Node B, and RNC_processing_delay is the RNC PHYSICAL CHANNEL. The amount of time it takes to receive a RECONFIGURATION message and send a RADIO BEARER RECONFIGURATION message, Uu_delay is the time it takes for the RADIO BEARER RECONFIGURATION message to be sent from Node B to the UE, and the UE_processing delay is the UE receives the RADIO BEARER RECONFIGURATION message. The time it takes to prepare for receiving data, Margin means any extra time. If the embodiment 1 or 2 of the present invention is applied, it may be applied in consideration of the time for receiving the PHYSICAL CHANNEL RECONFIGURATION Response message.

Equation 1 is equally applied to the calculation of the activation time of 103. However, the calculation of the activation time of the RNC in step 903 is compared with the time considering not only the situation that can be considered by the Node B, but also possible prediction times according to the current traffic state or the UE situation as described above. You can determine the actual activation time.

Steps 804, 805, and 806 are the same as steps 104, 105, and 106, and thus a detailed description thereof will be omitted. In step 807, the Node B receiving the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message from the RNC decodes the activation time included in the message and increases the current CFN by 1 for each frame elapsed to match the activation time. serving HS-SCCH It is possible to transmit data through the HS-SCCH corresponding to the set id.

Next, the operation of the base station controller according to the first embodiment of the present invention will be described with reference to FIG. 16.

16 is a flowchart illustrating operation of a base station controller according to a third embodiment of the present invention.

When the RNC receives the PHYSICAL CHANNEL RECONFIGURATION REQUEST message (901), the RNC decodes the new serving HS-SCCH set id and the preferred activation time included in the message (902). The RNC determines the activation time using the preferred activation time received from the Node B as in the method shown in step 701 of FIG. 14 (903) and sends a PHYSICAL CHANNEL RECONFIGURATION RESPONSE message including the determined activation time. Transmit to Node B (905). In addition, after configuring a RADIO BEARER RECONFIGURATION message or PHYSICAL CHANNEL RECONFIGURATION message or TRANSPORT CHANNEL RECONFIGURATION message including a new serving HS-SCCH set id and activation time and transmits to the UE (904), when the process is completed as described above, the Node B and the UE transmit and receive data from the determined activation time through the HS-SCCH corresponding to the newly changed Serving HS-SCCH Set.

Herein, the operation of the UE for operating the third embodiment of the present invention is the same as the operation of the first and second embodiments of the present invention, and thus description thereof is omitted for convenience.                     

The configuration of the RADIO BEARER RECONFIGURATION message of the third embodiment is the same as that of the first and second embodiments. The formats of the PHYSICAL CHANNEL RECONFIGURATION REQUEST message and the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message of the third embodiment are shown in Table 8 below.

IE / Group Name Presence Message Discriminator M Message Type M CRNC Communication Context ID M Transaction ID M New Serving HS-SCCH set ID M Preferred Activation Time M

The PHYSICAL CHANNEL RECONFIGURATION RESPONSE message format is shown in Table 9 below.

IE / Group Name Presence Message Discriminator M Message Type M Node B Communication Context ID M Transaction ID M Activation Time M

In the message formats shown in Tables 8 and 9, other IEs are the same as in the first embodiment, and thus description thereof is omitted. In the third embodiment, the Preferred Activation Time is inserted into the PHYSICAL CHANNEL RECONFIGURATION REQUEST message. Preferred Activation Time is likewise coded with an appropriate value between 0 and 255. In the PHYSICAL CHANNEL RECONFIGURATION RESPONSE message, the activation time determined by the RNC is coded with a value between 0 and 255.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention enables direct transmission between a base station and a UE in transmitting HS-SCCH related information such as a serving HS-SCCH set allocated to a certain UE in a communication system using a fast forward packet access scheme. Has the advantage. In addition, by directly transmitting the HS-SCCH related information between the base station and the UE, it is possible to reduce signal delay between the base station and the UE and save Iub transmission resources, thereby improving system performance.

Claims (4)

A high speed forward common channel that spreads and transmits user data corresponding to first channelization code information shared by a plurality of user terminals and assigned to each of the plurality of user terminals; A method for transmitting reset information of serving high speed common control channel set information in a mobile communication system having a plurality of high speed common control channels for transmitting control information including at least the first channelization code information for terminals to receive, the method comprising: Among the plurality of second channelization codes allocated to each of the plurality of fast common control channels, a plurality of second channelization codes for spreading the fast common control channel are allocated to each of the plurality of fast common control channels. Generating a plurality of serving high speed common control channel sets by correlating the high speed common control channel with each other; Allocating one serving high speed common control channel set among the plurality of serving high speed common control channel sets to each of the user terminals, and managing a state in which the serving high speed common control channel set is allocated to each of the user terminals and, If it is detected that the serving high speed common control channel set allocated to a specific user terminal needs to be changed while managing the state, a new serving high speed common control channel set to be allocated to the specific user terminal is allocated, and the specific user terminal is assigned. Transmitting a message indicating that the serving high speed common control channel set is changed, And transmitting data to the new serving high speed common control channel from a specific time point after transmitting the message. A method for receiving serving high speed common control channel set information in a communication system using a high speed forward packet access method, Receiving a message indicating that the serving fast common control channel set has been changed from the base station controller; Analyzing the received message to analyze a serving high speed common control channel set to be newly set and a time point to which the newly set serving high speed common control channel set is actually applied; Analyzing the newly set serving high speed common control channel set and a time point to which the newly set serving high speed common control channel set is received, and receiving the high speed common control channel signal by applying the newly set serving high speed common control channel set information And receiving the serving high speed common control channel set information. The method of claim 1, And the message is a base station application part message. The method of claim 2, And the message is a base station application part message.

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