KR20030024473A - Apparatus for determining slot format of downlink dedicated physical channel in mobile communication system using high speed downlink packet access scheme and method thereof - Google Patents

Abstract

PURPOSE: An apparatus and a method for deciding a slot format of a DL_DPCH(DownLink_Dedicated Physical CHannel) in a mobile communication system using an HSDPA(High Speed Downlink Packet Access) type are provided to variably operate a downlink DPCH structure of active cells when a UE(User Element) is located in a soft hand-over region. CONSTITUTION: An SRNC(Serving Radio Network Controller) checks whether an active cell included in an active set about a UE is added(802). If the active cell is added, the SRNC checks whether the added new active cell is a cell which belongs to an HI(HS-DSCH(High Speed-Downlink Shared CHannel) Indicator) radio path set same to a cell which performs an HSDPA service about the UE(803). If the added new active cell is the cell which belongs to the HI radio path set, the SRNC decides a DL_DPCH slot format of the added new active cell as a slot format for transmitting the HI(804). If the added new active cell is not the cell which belongs to the HI radio path set, the SRNC decides the DL_DPCH slot format of the added new active cell as a slot format in which the HI is not transmitted(805). If the active cell is not added, the SRNC informs information about the DL_DPCH slot format decided as to the active cells which exist in the active set to a Node B and the UE(806).

Description

Apparatus and method for determining slot format of a forward dedicated physical channel in a mobile communication system using a high speed forward packet access method }

The present invention relates to a communication system using a fast forward packet access scheme, and more particularly, to an apparatus and method for determining a slot structure of a forward dedicated physical channel when a user terminal is located in a soft handover region.

In general, High Speed Downlink Packet Access (HSDPA) is a high-speed forward common, which is a forward data channel for supporting forward high-speed packet data transmission in a Universal Mobile Terrestrial System (UMTS) communication system. A data transmission method including a channel (High Speed Downlink Shared Channel (HS-DSCH)) and control channels related thereto is generically referred to. In order to support the HSDPA, an adaptive modulation and coding scheme (hereinafter referred to as "AMC"), a hybrid automatic retransmission request (hereinafter referred to as "HARQ"), and fast cell selection (fast cell) Select: (hereinafter referred to as "FCS") has been proposed.

First, the AMC method will be described.

The AMC scheme is a modulation scheme of different data channels depending on a channel state between a specific base station (Node B, hereinafter referred to as "Node B") and a terminal (UE: User Element, hereinafter referred to as "UE"). And a data transmission method for determining the coding method and improving the use efficiency of the entire base station. Accordingly, the AMC scheme has a plurality of modulation schemes and a plurality of coding schemes, and modulates and codes a data channel signal by combining the modulation schemes and coding schemes. Typically, each of the combinations of modulation schemes and coding schemes is referred to as a modulation and coding scheme (hereinafter, referred to as "MCS"), and level n to level n depending on the number of MCSs. Up to a plurality of MCSs can be defined. That is, the AMC scheme is a scheme for adaptively determining the level of the MCS according to the channel state between the UE and the Node B which is currently wirelessly connected to improve the overall Node B system efficiency.

Secondly, an HARQ scheme, in particular, a multi-channel Stop And Wait Hybrid Automatic Retransmission Request (hereinafter referred to as "n-channel SAW HARQ") will be described.

The HARQ scheme newly applies the following two methods to increase the transmission efficiency of the ARQ (Automatic Retransmission Request) scheme. The first scheme is to perform the retransmission request and response between the UE and the Node B. The second scheme is to temporarily store the data in error and combine it with the retransmission data of the corresponding data. will be. In addition, the HSDPA scheme has introduced the n-channel SAW HARQ scheme to compensate for the shortcomings of the conventional Stop and Wait ARQ (SAW ARQ) scheme. In the SAW ARQ scheme, the next packet data is transmitted only after receiving an ACK for the previous packet data. However, since the next packet data is transmitted only after receiving the ACK for the previous packet data, there may occur a case where the ACK should be waited even though the packet data may be transmitted at present. In the n-channel SAW HARQ scheme, a plurality of packet data may be continuously transmitted without receiving an ACK for the previous packet data, thereby improving channel usage efficiency. That is, if n logical channels are established between the terminal and the base station, and each of the n channels can be identified by a specific time or channel number, the UE that receives the packet data is received at any time. It is possible to know which packet data is transmitted through which channel, and may take necessary measures such as reconstructing the packet data in the order in which it is to be received or soft combining the packet data.

Finally, the FCS method will be described.

The FCS scheme is a method of quickly selecting a cell having a good channel state among a plurality of cells when the terminal using the HSDPA scheme is located in a cell overlap region, that is, a soft handover region. Specifically, the FCS scheme includes: (1) when a terminal using the HSDPA enters a cell overlap region of an old base station and a new base station, the terminal is configured to have a radio link with a plurality of cells, that is, a plurality of base stations. Radio Link ".) Is set. In this case, a set of cells in which a radio link is established with the terminal is called an active set. (2) Receive packet data for HSDPA only from cells that maintain the best channel state among the cells included in the active set to reduce the overall interference. Herein, a cell transmitting HSDPA packet data because the channel state is the best in the active set is called a best cell, and the terminal periodically checks the channel state of the cells belonging to the active set and compares it with the current best cell. When a cell having a better channel state occurs, a best cell indicator or the like is transmitted to cells belonging to the active set to change the current best cell into a cell having a better channel state. The best cell indicator includes an identifier of a cell selected as a best cell and is transmitted. Accordingly, cells in the active set receive the best cell indicator and examine a cell identifier included in the best cell indicator. Thus, each of the cells in the active set checks whether the best cell indicator corresponds to its best cell indicator, and the corresponding cell selected as the best cell is a packet to the terminal using a fast forward common channel (HS-DSCH). Send the data.

As described above, the HSDPA requires a fast decision of the Node B for fast data transmission between the UE and the Node B in order to support the newly introduced techniques. That is, the MCS level needs to quickly change the modulation and coding scheme by quickly detecting the forward channel state of the Node B, and the HARQ receives an ACK from the UE for the packet data transmitted from the Node B to the UE. You must quickly determine that you have failed to resend the packet data. As a result, the Node B must quickly perform functions such as scheduling the HSDPA service and storing retransmission packet data in a buffer.

1 is a diagram schematically illustrating a forward channel structure of a communication system using a conventional high speed forward packet access scheme.

Referring to FIG. 1, a downlink dedicated physical channel (DPCH) is an existing code division multiple access communication system, for example, a field defined in Release-99 and an HSDPA to be received by a terminal. It consists of a fast forward common channel indicator (HI: HS-DSCH Indicator, indicating "HI") indicating whether or not packet data exists. The HI transmitted through the forward dedicated physical channel not only indicates whether there is HSDPA packet data to be received by the corresponding terminal, but also controls the HS-DSCH in which the HSDPA packet data is actually transmitted when the HSDPA packet data exists. It may also inform the channelization code of a common control channel (SHCCH) that should receive information. In addition, if necessary, some of the HS-DSCH control information, for example, control information such as MCS level may be transmitted through the HI.

For example, when the HSDPA packet data is transmitted in units of N (= N ₁ + N ₂ ) slots (ie, HSDPA transmission time interval (TTI = N slot)), the slot structure in the TTI Is fixed unchanged, the HI is divided into N ₁ slots and transmitted, and the part transmitting HI in the remaining N ₂ slots is treated as discontinuous transmission (DTX). In FIG. 1, since HI is transmitted only through one slot, it is assumed that N ₁ is 1.

In addition, the base station determines the MCS level, HS-DSCH channelization code, HARQ process number, HARQ packet number, etc., which are information for controlling the HS-DSCH channel (hereinafter referred to as HS-DSCH control information). Hereinafter, it transmits to the terminal through SHCCH). Here, the HS-DSCH control information will be described.

(1) MCS level: Informs the modulation and channel coding method to be used in the HS-DSCH channel.

(2) HS-DSCH channelization code: channelization code used for a specific terminal in the HS-DSCH channel

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

(4) HARQ packet number: When the best cell is changed in the FCS, the terminal informs the terminal of the number of forward packet data so that the terminal can inform the newly selected best cell of the transmission state of the HSDPA data.

One or more channelization codes may be allocated to the SHCCH. In FIG. 1, up to four SHCCHs can be allocated to each of the UEs. Therefore, the HI of the DPCH informs the SHCCH channel of the UE to be received along with the presence or absence of the HSDPA data packet to be received. Since the number of SHCCHs can be allocated up to four, two bits (2 bits) of HI can inform the information on the SHCCH to be received by the UE. For example, if HI is 00, the UE receives SHCCH # 1, 01 receives SHCCH # 2, 10 receives SHCCH # 3, and 11 receives SHCCH # 4. The HS-DSCH is a channel through which HSDPA packet data transmitted from the base station to the terminal is transmitted.

Next, a process of receiving the HSDPA service by the UE using three channels as described above, that is, DPCH, SHCCH, and HS-DSCH will be described.

First, the UE demodulates a bit transmitted to the HI field by receiving a forward DPCH signal. If the HI field is DTX, the UE recognizes that there is no HSDPA packet data to be received and waits until the next TTI while receiving only the DPCH. Meanwhile, if a specific bit value is transmitted to the HI, the UE recognizes that HSDPA packet data exists and receives a corresponding SHCCH signal according to the HI bit value. Then, the corresponding SHCCH signal is read to extract the MCS level, channelization code, and HARQ-related control information of the HS-DSCH necessary for demodulating the HS-DSCH channel. Finally, the UE detects HSDPA packet data by receiving and demodulating an HS-DSCH signal using control information detected through the SHCCH.

As described above, in order to demodulate the HS-DSCH signal, the UE must read the SHCCH signal to detect the corresponding control information. That is, as shown in FIG. 1, the UE first receives DPCH and SHCCH signals, reads control information, and then receives an HS-DSCH channel. As a result, the forward DPCH start time is earlier than the start time of SHCCH and HS-DSCH, which is determined whether the other two channels are data corresponding to the UE before the UE reads the HS-DSCH indicator and detects the corresponding information. Because can not. That is, since the data corresponding to the UE cannot be known before the HS-DSCH indicator is read, the data must be temporarily stored in a buffer, so that the time for reading the HS-DSCH indicator is allowed, Receiving a channel to relieve the UE buffer burden. As a result, the UE reads the HS-DSCH indicator portion of the forward DPCH to check whether there is HSDPA packet data to be received by the UE itself, and if the HSDPA packet data to be received by the UE itself is found, the UE After reading information for controlling the HS-DSCH channel of the SHCCH, the HSDPA packet data is received through the HS-DSCH channel according to the control information. In addition, the HI for supporting the HSDPA service should be fairly reliable. The reason is that HI informs the UE whether there is HSDPA packet data to be received, and if the UE does not properly inform whether the HSDPA packet data exists, the UE may not receive the HSDPA service at the time of receiving HSDPA service. Because it can occur.

FIG. 2 is a diagram schematically illustrating a forward dedicated physical channel structure of a conventional code division multiple access communication system and a communication system using a high speed forward packet access scheme.

Referring to (a) of FIG. 2, first, the forward DPCH illustrates a structure of a code division multiple access communication system that does not support an existing HSDPA service, for example, a forward dedicated physical channel defined in Release-99. Each field is described as follows. The Data1 and Data2 fields transmit data for supporting a dedicated service such as data or voice for supporting higher layer operations. A Transfer Power Control (TPC) field transmits a downlink transmit power control command for controlling uplink transmit power, and a Transfer Format Combination Indicator (TFCI) field indicates the Data1. And transport format combination information of the Data2 field. The pilot field is a field for transmitting a predetermined pilot symbol string in a system, which is used by the UE to estimate a forward channel state.

Referring to FIG. 2 (b), the conventional high speed first forward DPCH includes a code division multiple access communication system that does not support the existing HSDPA service, for example, a structure of a forward dedicated physical channel defined in Release-99. Each field is described as follows. The Data1 and Data2 fields transmit data for supporting dedicated services such as voice or data for supporting higher layer operations. A Transfer Power Control (TPC) field transmits a downlink transmit power control command for controlling uplink transmit power, and a Transfer Format Combination Indicator (TFCI) field indicates the Data1. And transport format combination information of the Data2 field. The pilot field is a field for transmitting a predetermined pilot symbol sequence in the system, which is used by the terminal to estimate the forward channel state. The HI for the HSDPA service is transmitted to the terminal through a newly defined field in the existing Release-99 forward dedicated physical channel as shown in FIG. As a result, a HI field for notifying the UE of the presence or absence of the HSDPA data packet is newly included in the existing forward DPCH structure. If the forward DPCH of the communication system using the HSDPA scheme uses the same Spreading Factor (SF) as the DPCH defined in the existing Release-99, the forward directions of FIGS. 2A and 2B are used. The number of bits that can be transmitted on the DPCH is the same. Therefore, when the HI field is inserted in the forward DPCH channel in FIG. 2 (b), a part of the TFCI field or the pilot field in the existing forward DPCH structure should be allocated as a field for transmitting the HI. That is, since two bits of information are not transmitted in any one field, the HI is allocated as a field for transmitting the HI. FIG. 2B illustrates a case where the HI field is allocated by one bit in the TFCI field and the pilot field.

As described above, when the UE starts to support the HSDPA service, the UE does not support the HSDPA service, that is, supports the DPCH signal and the HSDPA service having the slot format as shown in FIG. It should be able to receive all of the DPCH signal having a slot format as shown in (b) of FIG. The UE also needs to be able to receive both a DPCH signal with a slot format that supports the HSDPA service and a DPCH signal with a slot format that does not support the HSDPA service. The Node B is a cell that does not support the existing HSDPA service, for example, a Release-99 cell is a DPCH signal having a slot format as shown in FIG. 2A, and a cell that supports the HSDPA service. The Release-5 cell is configured to transmit the slot format DPCH signal as shown in FIG.

However, as described above, if Node B transmits a DPCH signal having a corresponding slot format only according to whether it is a Release-99 cell or a Release-5 cell, efficiency of data transmission may be reduced. For example, when the Release-5 cell transmits a DPCH signal having a slot format as shown in FIG. 2B when the UE does not provide HSDPA service to the UE, the UE always receives HI even though the UE does not receive HSDPA service. This causes a problem of unnecessarily transmitting fields. In particular, such problems occur more seriously in cases where the service types provided by a plurality of Node Bs are different from each other, such as when the UE exists in a soft handover area. Therefore, there is a need for a method of adaptively operating the DPCH slot format in consideration of the service status of the Node B or the UE.

Accordingly, an object of the present invention is to provide a method of variably operating a forward dedicated physical channel structure of active cells when a user terminal is located in a soft handover area in a communication system using a fast forward packet access scheme.

Another object of the present invention is to provide a method for operating a forward dedicated physical channel structure including a fast forward common channel indicator only as a best cell when a user terminal is located in a soft handover area in a communication system using a fast forward packet access scheme. Is in.

The present invention for achieving the above object is to check whether the active cell of the user terminal is added when the user terminal currently receiving the fast forward packet access service enters the soft handover area, and the active cell is added as a result of the check In this case, the slot format of the dedicated physical channel for the active cell may be one of a slot format including a fast forward common channel indicator or a slot format not including the fast forward common channel indicator according to a communication service situation of the communication system and the user terminal. Characterized by determining.

1 schematically illustrates a forward channel structure of a communication system using a conventional high speed forward packet access scheme.

FIG. 2 schematically illustrates a forward dedicated physical channel structure of a conventional code division multiple access communication system and a communication system using a high speed forward packet access scheme; FIG.

3 is a schematic diagram illustrating a soft handover of a user equipment (UE) in a communication system using a high speed forward packet access method.

4 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format according to a first embodiment of the present invention.

5 is a flowchart illustrating a process of demodulating a forward dedicated physical channel signal of a user terminal according to a first embodiment of the present invention;

6 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format according to a second embodiment of the present invention.

7 is a flowchart illustrating a process of demodulating a forward dedicated physical channel signal of a user terminal according to a second embodiment of the present invention.

FIG. 8 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format when an SRNC knows a radio path between all cells and a UE according to a third embodiment of the present invention.

FIG. 9 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format when an SRNC does not know a radio path between all cells and a UE according to a third embodiment of the present invention.

10 is a block diagram showing an internal configuration of a base station performing a function in an embodiment of the present invention.

11 is a block diagram showing an internal configuration of a user terminal performing a function in an embodiment of the present invention.

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.

3 is a diagram schematically illustrating a soft handover of a user equipment (UE) in a communication system using a fast forward packet access scheme.

Referring to FIG. 3, first, three base stations (Node B), that is, Node B 1 305, Node B 2 306, and Node B 3 are set in an active set of a user terminal (UE) 318. Assume that 307 is present, and the Node B 1 305 and the Node B 2 306 are the base station controller (RNC: Radio Network Controller, hereinafter referred to as "RNC") A 302, It is assumed that the Node B 1 307 belongs to the RNC B 304. In addition, the Node B 1 305 and the Node B 2 306 are Release-5 cells capable of supporting the HSDPA service, and the Node B 3 307 is a Release-99 cell not supporting the HSDPA service. Assume In FIG. 3, a radio network system (RNS: hereinafter referred to as "RNS") is a combination of the RNC and Node Bs controlled by the RNC in a third generation asynchronous mobile communication standard. RNS A 301 includes Node B 1 305 and Node B 2 306 controlled by RNC A 302 and RNC A 302, and RNS B 303 is RNC B. 304 and Node B 3 307 under the control of RNC B 304.

Since the RNC currently being serviced by the UE 318 is the RNC A 302, the RNC A 302 becomes a SRNC (hereinafter referred to as a “SRNC”), and the RNC B ( 304 is called DRNC (Drift RNC, hereinafter referred to as "DRNC"). Here, the SRNC refers to an RNC that manages a service for a certain UE and is in charge of connection with a core network (hereinafter referred to as "CN"), and the DRNC refers to data for a certain UE. Among the RNCs to process, the remaining RNCs other than the SRNC are referred to.

Next, the structure in which the UE 318 actually performs a soft handover is as follows.

First, the UE 318 is a downlink dedicated physical channel (DL_DPCH: Downlink_Dedicated Physical CHannel), common control channel (SHCCH, fast forward) from the cell 1 (308) in Node B 1 (305) The HSDPA service is carried out using high speed-downlink shared channel (HS-DSCH) signals 313 and moves away from the cell 1 308. Then, the UE 318 performs a soft handover to simultaneously receive a channel signal of another cell whose reception signal strength is large enough together with the cell 1 308 currently receiving HSDPA service. The UE 318 continuously monitors the reception signals of a plurality of cells and sequentially includes cells having the high strength of the reception signal in the active set of the UE 318. In this manner, cell 2 309, cell 3 310, and cell 4 311 in Node B 2 306, and Node B 3 307 in Node B 2 306. Cell 5 312 is included in the active set of the UE 318. Thus, the UE 318 receives DL_DPCH signals 313, 314, 315, 316, and 317 simultaneously from the other cells in the active set together with the cell 1 308.

In FIG. 3, when the UE 318 receives the HSDPA service from the cell 1 308, the channels transmitted in the forward cell 1 308 are DL_DPCH, SHCCH for the HSDPA service, and HS-DSCH. On the other hand, other cells in the active set of the UE 318, that is, cell 2 (309), cell 3 (310), cell 4 (311), cell 5 (312) transmits only the DL_DPCH to the UE (318). This is because the HS-DSCH does not support soft handover. Since the HS-DSCH is a channel for transmitting high-speed packet data for the HSDPA service, the high-speed packet data is transmitted from one Node B to another. Thus, when the UE 318 is located in the soft handover area while receiving the HSDPA service, the UE 318 may receive the SHCCH and HS-DSCH for the HSDPA service only from the cell 1 308, and from the other cells in the active set Only DL_DPCH carrying layer signaling data or voice service data and dedicated physical control information is received.

The UE 318 soft combines and interprets DL_DPCH signals received from five cells in the active set. In this case, the soft combining means that the UE 318 receives signals received through different paths through a finger and combines them, and the purpose of the soft combining is received through different paths. After summing the same information, it is interpreted to give the UE 318 a multipath diversity effect on the received signal to reduce the influence of noise affecting the received signal. Since the soft combining is possible only when the same information is received from the different cells for the UE 318, the soft combining is performed when different information is being received at the UE 318 from each cell. It does not work because it only increases the noise component.

Therefore, if the UE 318 receives DL_DPCHs in a slot format that does not transmit HI as described in FIG. 2A from all cells in the active set, except for the TPC, Data1, TFCI, and Data2. And Pilot are all soft combined and interpreted. Here, the reason why the TPC is not soft-combined and separately interpreted is that the position of the TPC is not constant because the UE 318 moves, so that the signal of the UE 318 received by the Node B 1 305 receives its signal strength. Is large, the signal of the UE 318 received by the Node B 2 306 may be a weak signal strength, or vice versa, the TPC value received at each Node B This may be different. In addition, as described above, the TPC may be soft-combined and interpreted. In this case, when cells in a Node B are the same radio path set, cells transmit the same TPC value to the UE 318 for the same radio path set. It is limited to. In this case, since the TPC values of the cells are the same, the UE 318 may soft-combine and interpret all the TPCs together with the Data1, TFCI, Data2, and Pilot of all DL_DPCHs.

As described with reference to FIG. 3, when the UE is located in the soft handover region, a multipath diversity effect can be obtained by soft combining DL_DPCH signals received from a plurality of cells present in the active set of the UE. In addition, the HI is information indicating whether the HSDPA data is actually transmitted. Therefore, the HI is information that should be guaranteed a considerable reliability. Therefore, in the embodiment of the present invention, when the UE is located in the soft handover region in consideration of the two aspects described above, that is, DL_DPCH signals are soft combined and interpreted, and the HI should have high reliability. A method of determining a slot format of DL_DPCH of cells in an active set of the UE is provided.

Next, a method of determining a slot format of DL_DPCH of cells in an active set of the UE when the UE is located in a soft handover area will be described with reference to FIG. 3.

First, since cell 1 308 provides HSDPA service to UE 318, the DL_DPCH 313 slot format of cell 1 308 is a slot format for transmitting HI as described in FIG. 2 (b). Must have Since cell 5312 is a cell that does not support the HSDPA service, that is, a Release-99 cell, the DL_DPCH 317 slot format of cell 5312 should have a slot format that does not transmit the HI. In this manner, the cell 1 308 and the cell 5 312 are determined by the specific slot format as described above. The remaining cells in the active set, that is, the cell 2 309, the cell 3 310, and the cell 4 311 The method of determining the DL_DPCH slot format is determined by three rules as follows.

(1) Rule 1

Since HI information is not required for the remaining cells not currently serving HSDPA, all of them are determined as DL_DPCH slot format that does not transmit HI.

(2) Rule 2

All cells belonging to the HI radio path set, such as a cell currently serving HSDPA, use the DL_DPCH slot format for transmitting HI, and support HSDPA service for cells belonging to a HI radio path set different from the cell serving the current HSDPA service. If the cell is to be released, that is, the Release-5 cell, the DL_DPCH slot format for transmitting HI is determined, but the HI field is DTX processed and if the cell does not support HSDPA service, that is, for the Release-99 cell, the DL_DPCH slot format is not transmitted Decide

(3) Rule 3

All cells belonging to the HI radio path set, such as a cell currently serving HSDPA, use the DL_DPCH slot format for transmitting HI, and HI information about the remaining cells not belonging to the HI radio path set, such as the cell serving the current HSDPA service. Is not required, so all of them are determined as DL_DPCH slot formats that do not transmit HI.

Three rules for determining the DL_DPCH slot format are summarized in Table 1 below.

Next, each of the three metrics described above will be described in detail.

First, the "rule 1" will be described as follows.

Rule 1 is a case in which all of the remaining cells that do not currently serve HSDPA do not need HI information, so that all of them determine the DL_DPCH slot format that does not transmit HI. In general, a DL_DPCH slot format does not transmit HI defined for cells that do not support HSDPA services, that is, a Release-99 cell, and a DL_DPCH slot transmits HI defined for cells supporting an HSDPA service, that is, a Release-5 cell. Consider the case of keeping the format as it is. In FIG. 3, DL_DPCH of Cell 1 308, Cell 2 309, Cell 3 310, and Cell 4 311, which are Release-5 cells, uses a slot format for transmitting HI and Cell 5 (Release-99 cell). 312 uses a DL_DPCH slot format that does not transmit HI. However, since the HSDPA service is currently provided by the cell 1 308 for the UE 318, the HI bit is transmitted only to the HI field of the cell 1 308, and supports the remaining cells, that is, the HSDPA service, but currently the HSDPA service. HI fields of Cell 2 (309), Cell 3 (310), and Cell 4 (311) that do not have DTX processing are DTX processed. As a result, since the cell 2 309, the cell 3 310, and the cell 4 311 are transmitted in the DL_DPCH slot format for transmitting the HI without actually performing the HSDPA service, the HI field is DTX-treated. Even the data excludes the possibility of being transmitted. The reason is that if the spreading rate (SF) of the DL_DPCH slot format for transmitting HI and the DL_DPCH slot format for transmitting HI is the same, the DL_DPCH slot format for transmitting HI is used to generate an HI field in the DL_DPCH slot format for transmitting HI. This is because the amount of other data (eg TFCI, Pilot) has been reduced. Thus, in rule 1, DL_DPCH of cells 2 (309), cells 3 (310), and cells 4 (311), which do not need to transmit HI, has a structure as shown in FIG. Send it. Of course, cell 5312, which is a Release-99 cell that cannot transmit HI, transmits the DL_DPCH signal in a slot format having no HI field. In this way, cells that do not need to transmit HI transmit a DL_DPCH without reducing the amount of transmitted data such as Data1, TPC, TFCI, Data2, and Pilot defined in Release-99 using a slot format that does not transmit HI. Possible to increase the soft combining effect of the data other than the HI in the UE (318).

Secondly, the "rule 2" will be described as follows.

In Rule 2, all cells belonging to the HI radio path set, such as a cell currently serving HSDPA, use the DL_DPCH slot format for transmitting HI, and for a cell belonging to a HI radio path set different from the cell serving the current HSDPA service. If the cell supports HSDPA service, that is, Release-5 cell, it is determined as DL_DPCH slot format for transmitting HI, but DTX processing the HI field, and if the cell does not support HSDPA service, that is, Release-99 cell, HI is not transmitted In case of determining the DL_DPCH slot format, the rule 2 increases the HI soft combining effect. In the following description of Rule 2, the definition of the "HI radio path set" will be described.

Prior to defining the "HI radio path set", it has been described that providing and scheduling the HSDPA service is performed by the Node B rather than the upper layer RNC. That is, since Node B manages HSDPA service provided by each cell, it knows HI or other control information generated by each cell. There are cells in the Node B using the same processor for the HSDPA service. A set of cells using the same processor for the HSDPA service is defined as "HI radio path set." As a result, the cells in the HI radio path set know each other's HI information or other control information generated for the HSDPA service. In general, Node B may be a set of HI radio paths or there may be several HI radio path sets in Node B. In FIG. 3, it is assumed that cell 1 308 and cell 2 309 are the same HI radio path set, and cell 3 310 is a different radio path set.

Therefore, when Cell 1 308 is currently providing HSDPA service to UE 318, the Cell 1 308 and the Cell 2 309 are the same HI radio path aggregation and thus the HI generated by Cell 1 308 The cell 2 309 also knows the bit. Thus, the cell 2 309 may transmit HI bit information transmitted by the cell 1 308 in the cell 2 309 itself. In general, the UE transmits the same HI bit to all cells in the HI radiopath set to which the cell providing the HSDPA service belongs so that the UE can have a soft combining effect on the HI. Meanwhile, for the cell belonging to a different HI radio path set than the cell 1 308 that provides the current HSDPA service, that is, the cell 3 310 for the cell 3 310, the cell 4 311, and the cell 5 312. Cell 4311 determines the DL_DPCH slot format for transmitting HI, but performs DTX processing on the HI field, and cell 5312 determines the DL_DPCH slot format for transmitting HI.

Meanwhile, in Rule 2, it may be considered to use the DL_DPCH slot format having the DL_DPCH slot format for transmitting the HI and not transmitting the HI to a cell for DTX processing the HI. In this case, the rule 3 Corresponds to

Third, the "rule 3" will be described as follows.

Rule 3 is that all cells belonging to the HI radio path set, such as a cell currently serving HSDPA, use the DL_DPCH slot format for transmitting HI, and remaining cells not belonging to the HI radio path set, such as the cell currently serving HSDPA service. Since HI information is not needed for all of them, all of them are determined as DL_DPCH slot formats that do not transmit HI. That is, for the cell 1 308 which is the cell currently serving the HSDPA service and the cell 2 309 existing in the same HI radio path set as the cell 1 308, the UE 318 is determined as the DL_DPCH slot format for transmitting HI. ) Has a HI soft combining effect, and for cells not belonging to the same HI radio path set as the cell 1 308, that is, the cell 3 310, the cell 4 311, and the cell 5 312. Determine the DL_DPCH slot format that does not transmit HI so that the UE 318 increases the soft combining effect without reducing the amount of data other than the HI, i.e., Data1, TPC, TFCI, Data2, Pilot data transmission. do.

Next, a process of determining the DL_DPCH slot format using the rules 1 to 3 will be described next. First, a process of determining the DL_DPCH slot format using the rule 1 will be described with reference to FIGS. 4 to 5. This will be described. Here, the case corresponding to rule 1 is the first embodiment of the present invention, the case corresponding to rule 2 is the second embodiment of the present invention, and the case corresponding to rule 3 is the third embodiment of the present invention. This will be referred to as an example.

4 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format according to a first embodiment of the present invention.

FIG. 4 is a first embodiment of the present invention, i.e., a DL_DPCH slot format for transmitting HI only to a cell performing an HSDPA service among cells belonging to an active set, and DL_DPCH slot format for rest cells not to transmit HI The case where it determines is shown. First, in step 402, the SRNC 302 checks whether an active cell included in an active set for the UE 318 is added. In this case, when the UE 318 is receiving HSDPA service from only one cell and moves away from the cell, the UE 318 is present in a soft handover area affected by other cells, and is present in the soft handover area. An active set of the UE 318 is generated, and a plurality of active cells are present in the active set. If the active cell is added as a result of the check in step 402, the SRNC 302 proceeds to step 403. In step 403, the SRNC 302 determines the DL_DPCH slot format of the added new active cell as a slot format that does not transmit HI and returns to step 402. Here, the reason why the SRNC 302 determines the DL_DPCH slot format of the added new active cell as a slot format that does not transmit HI is because the SRNC 302 is an RNC following the rule 1 described above.

If the active cell is not added as a result of the check in step 402, the SRNC 302 proceeds to step 404. In step 404, the SRNC 302 informs the Node B and the UE 318 of the DL_DPCH slot format determined for the active cells present in the active set and ends. In this case, the SRNC 302 determines the DL_DPCH slot format determined for the active cells using a Node B Application Part (NBAP) message, which is a signaling message between the SRNC 302 and Node B. Notify Node B. The NBAP message refers to a signaling message between the RNC and the Node B. The NBAP message may select one of the NBAP messages, for example, a Radio Link Setup message, and transmit the determined DL_DPCH slot format. In the standard of the asynchronous system among the messages of the Radio Link Setup, DL_DPCH Slot Format indicates a DPCH slot format for each cell. In step 404, the SRNC 302 transmits the determined DL_DPCH slot format information to the corresponding Node B and simultaneously transmits the determined DL_DPCH slot format information to the UE 318. Here, the determined DL_DPCH slot format information is delivered to the UE 318 through a Radio Resource Control (RRC) message, which is an upper layer signaling message. For example, the SRNC 302 is a cell using a DL_DPCH slot format that transmits HI to the UE 318 through the RRC message, and a cell using a DL_DPCH slot format that does not transmit HI. It can tell you if it is a cell.

As described with reference to FIG. 4, when the SRNC 302 determines the slot format for the DL_DPCH for the UE 318, the DL_DPCH signal demodulation process of the UE 318 will be described with reference to FIG. 5.

5 is a flowchart illustrating a process of demodulating a forward dedicated physical channel signal of a user terminal according to a first embodiment of the present invention.

Referring to FIG. 5, in step 502, the UE 318 receives information on a DL_DPCH slot format transmitted from each cell in an active set through an RRC message from the SRNC 302, and proceeds to step 503. In step 503, the UE 318 first allocates the DL_DPCH signal received from the cells to a finger regardless of its slot format, and proceeds to step 504. In this case, the UE 318 can be allocated to the finger regardless of the slot format of the DL_DPCH so that the UE 318 can receive both the DL_DPCH slot format for transmitting HI and the DL_DPCH signals for the DL_DPCH slot format for not transmitting HI. Because it has. That is, it is possible to demodulate both the DL_DPCH slot format for transmitting HI and the DL_DPCH signal for DL_DPCH slot format without HI. Since the hardware structure of the UE 318 will be described with reference to FIG. 11 below, a detailed description thereof will be omitted.

In step 504, the UE 318 checks whether the DL_DPCH of each cell has a slot format for transmitting HI for each of the fingers to which the DL_DPCH signal is allocated. If the result of the check is a DL_DPCH signal having the slot format for transmitting the HI, the UE 318 proceeds to step 505. In step 505, the UE 318 transfers the received DL_DPCH signal to a demodulator capable of conforming to a slot format for transmitting HI from a finger, and proceeds to step 507. If the result of the check in step 504 is not a DL_DPCH signal having the slot format for transmitting the HI, the UE 318 proceeds to step 506. In step 506, the UE 318 transfers the received DL_DPCH signal to a demodulator capable circuit suitable for a slot format that does not transmit the HI in a finger, and proceeds to step 507. In step 507, the UE 318 soft-combines Data 1, Data 2, TPC, TFCI, and Pilots except HI, among the DL_DPCH data demodulated by the finger circuits, to obtain a multipath diversity effect, and then ends. . In this case, since the HI is received only from the cell currently receiving the HSDPA service, the HI does not go through the soft combining process.

Secondly, a process of determining the DL_DPCH slot format using Rule 2 will be described with reference to FIGS. 6 to 7.

6 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format according to a second embodiment of the present invention.

FIG. 6 shows a second embodiment of the present invention, that is, a DL_DPCH slot format for transmitting HI for all cells belonging to the same HI radio path set as a cell for performing an HSDPA service among cells belonging to an active set. For cells belonging to a set of HI radio paths different from a cell currently performing HSDPA service, a cell supporting HSDPA service is determined as a DL_DPCH slot format for transmitting HI, and a cell not supporting the HSDPA service does not transmit HI. The case of determining the DL_DPCH slot format is illustrated. First, in step 602, the SRNC 302 checks whether an active cell included in an active set for the UE 318 is added. In this case, when the UE 318 is receiving HSDPA service from only one cell and moves away from the cell, the UE 318 is present in a soft handover area affected by other cells, and is present in the soft handover area. An active set of the UE 318 is generated, and a plurality of active cells are present in the active set. If the active cell is added as a result of the check in step 602, the SRNC 302 proceeds to step 603.

In step 603, the SRNC 302 checks whether the added new active cell belongs to the same HI radio path set as the cell currently performing HSDPA service for the UE 318. If the added new active cell is a cell belonging to the same HI radio path set as the cell currently performing the HSDPA service, the SRNC 302 proceeds to step 604. In step 604, the SRNC 302 determines the DL_DPCH slot format of the added new active cell as a slot format for transmitting HI and returns to step 602. In step 603, if the added new active cell is not a cell belonging to the same HI radio path set as the cell currently performing the HSDPA service, the SRNC 302 proceeds to step 605. In step 6O5, the SRNC 302 checks whether the added new active cell is a cell capable of supporting the HSDPA service, that is, a Release-5 cell. If the added new active cell is a cell capable of supporting the HSDPA service, the SRNC 302 proceeds to step 604. On the other hand, if the new active cell added as a result of the check in step 605 is not a cell capable of supporting the HSDPA service, the SRNC 302 proceeds to step 606. In step 606, the SRNC 302 determines the DL_DPCH slot format of the added new active cell as a slot format that does not transmit HI and returns to step 602.

On the other hand, if the active cell is not added as a result of the check in step 602, the SRNC 302 proceeds to step 607. In step 607, the SRNC 302 informs the Node B and the UE 318 of the DL_DPCH slot format determined for the active cells in the active set and ends. Here, the information on the DL_DPCH slot format determined by the SRNC 302 for the active cells is a Node B Application Part (NBAP) which is a signaling message between the SRNC 302 and the Node B as described with reference to FIG. 4. Message to the corresponding Node B. The NBAP message refers to a signaling message between the RNC and the Node B. The NBAP message may select one of the NBAP messages, for example, a Radio Link Setup message, and transmit the determined DL_DPCH slot format. In the standard of the asynchronous system among the messages of the Radio Link Setup, DL_DPCH Slot Format indicates a DPCH slot format for each cell. In step 607, the SRNC 302 transmits the determined DL_DPCH slot format information to the corresponding Node B and simultaneously transmits the determined DL_DPCH slot format information to the UE 318. Here, the determined DL_DPCH slot format information is delivered to the UE 318 through a Radio Resource Control (RRC) message, which is an upper layer signaling message. For example, the SRNC 302 is a cell using a DL_DPCH slot format that transmits HI to the UE 318 through the RRC message, and a cell using a DL_DPCH slot format that does not transmit HI. It can tell you if it is a cell.

As described with reference to FIG. 6, when the SRNC 302 determines the slot format for the DL_DPCH for the UE 318, the DL_DPCH signal demodulation process of the UE 318 will be described with reference to FIG. 7.

7 is a flowchart illustrating a process of demodulating a forward dedicated physical channel signal of a user terminal according to a second embodiment of the present invention.

Referring to FIG. 7, in step 702, the UE 318 receives information on a DL_DPCH slot format transmitted from each cell in an active set through an RRC message from the SRNC 302, and proceeds to step 703. In step 703, the UE 318 first allocates the DL_DPCH signal received from the cells to a finger regardless of its slot format, and proceeds to step 704. In this case, the UE 318 can be allocated to the finger regardless of the slot format of the DL_DPCH so that the UE 318 can receive both the DL_DPCH slot format for transmitting HI and the DL_DPCH signals for the DL_DPCH slot format for not transmitting HI. Because it has. That is, it is possible to demodulate both the DL_DPCH slot format for transmitting HI and the DL_DPCH signal for DL_DPCH slot format without HI. Since the hardware structure of the UE 318 will be described with reference to FIG. 11 below, a detailed description thereof will be omitted.

In step 704, the UE 318 checks whether the DL_DPCH of each cell has a slot format for transmitting HI for each of the fingers to which the DL_DPCH signal is allocated. If the result of the check is a DL_DPCH signal having the slot format for transmitting the HI, the UE 318 proceeds to step 705. In step 705, the UE 318 transmits the received DL_DPCH signal to a demodulator circuit suitable for a slot format for transmitting HI from a finger, and proceeds to step 707. If the result of the check in step 704 is not a DL_DPCH signal having the slot format for transmitting the HI, the UE 318 proceeds to step 706. In step 706, the UE 318 transmits the received DL_DPCH signal to a demodulator capable of conforming to a slot format that does not transmit the HI in a finger, and demodulates. In step 707, the UE 318 has DL_DPCH data demodulated in each finger circuit, HI is soft combined with HI, and Soft 1 is combined with Data 1, Data 2, TPC, TFCI, and Pilots except for HI. Inning ends after obtaining multipath diversity effect.

Third, a process of determining the DL_DPCH slot format using the rule 3 will be described with reference to FIGS. 8 to 9. In the third embodiment, that is, among the cells belonging to the active set, all cells belonging to the same HI radio path set as the cell performing the current HSDPA service are determined as DL_DPCH slot format for transmitting HI, and performing the current HSDPA service. This is a case where a DL_DPCH slot format for not transmitting HI is determined for a cell belonging to an HI radio path set different from the cell. In the first and second embodiments, the SRNC assumes that all Node Bs may know information about the radio path between each cell and the UE. In the third embodiment, the SRNC uses the radio path. We will consider both cases where we know information about and where we may not know about the radio path.

8 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format when the SRNC knows a radio path between all cells and a UE according to a third embodiment of the present invention.

FIG. 8 will be described in the third embodiment where it is assumed that the SRNC can know the information on the radio path between each cell and the UE for all Node Bs. First, in step 802, the SRNC 302 checks whether an active cell included in an active set for the UE 318 is added. In this case, when the UE 318 is receiving HSDPA service from only one cell and moves away from the cell, the UE 318 is present in a soft handover area affected by other cells, and is present in the soft handover area. An active set of the UE 318 is generated, and a plurality of active cells are present in the active set. If the active cell is added as a result of the check in step 802, the SRNC 302 proceeds to step 803.

In step 803, the SRNC 302 checks whether the added new active cell belongs to the same HI radio path set as the cell currently performing HSDPA service for the UE 318. If the added new active cell is a cell belonging to the same HI radio path set as the cell currently performing the HSDPA service, the SRNC 302 proceeds to step 804. In step 804, the SRNC 302 determines the DL_DPCH slot format of the added new active cell as a slot format for transmitting HI and returns to step 802. If the new active cell added as a result of the check in step 803 does not belong to the same HI radio path set as the cell currently performing the HSDPA service, the SRNC 302 proceeds to step 805. In step 805, the SRNC 302 determines the DL_DPCH slot format of the added new active cell as a slot format that does not transmit HI and returns to step 802.

If the active cell is not added as a result of the check in step 802, the SRNC 302 proceeds to step 806. In step 806, the SRNC 302 informs the Node B and the UE 318 of the DL_DPCH slot format determined for the active cells in the active set and ends. Here, the information on the DL_DPCH slot format determined by the SRNC 302 for the active cells is a Node B Application Part (NBAP) which is a signaling message between the SRNC 302 and the Node B as described with reference to FIG. 4. Message to the corresponding Node B. The NBAP message refers to a signaling message between the RNC and the Node B. The NBAP message may select one of the NBAP messages, for example, a Radio Link Setup message, and transmit the determined DL_DPCH slot format. In the standard of the asynchronous system among the messages of the Radio Link Setup, DL_DPCH Slot Format indicates a DPCH slot format for each cell. In step 806, the SRNC 302 transmits the determined DL_DPCH slot format information to the corresponding Node B and simultaneously transmits the determined DL_DPCH slot format information to the UE 318. Here, the determined DL_DPCH slot format information is delivered to the UE 318 through a Radio Resource Control (RRC) message, which is an upper layer signaling message. For example, the SRNC 302 is a cell using a DL_DPCH slot format that transmits HI to the UE 318 through the RRC message, and a cell using a DL_DPCH slot format that does not transmit HI. It can tell you if it is a cell.

8 illustrates a case in which the SRNC knows a radio path between all Node Bs and a UE in the third embodiment. Next, in the third embodiment, the SRNC is radio between all the Node Bs and the UE. The case where the path is not known will be described with reference to FIG. 9.

9 is a flowchart illustrating a process of determining a forward dedicated physical channel slot format when the SRNC does not know the radio path between all cells and the UE in the third embodiment of the present invention.

Referring to FIG. 9, first, since the SRNC 302 does not know the radio path information, Node B should transmit information on the radio path of the cells in the Node B to the SRNC 302. First, in step 902, the SRNC 302 requests radio path information from Node B and proceeds to step 903. Herein, the radio path information is information on the number of radio paths allocated in the Node B and how the radio paths form a HI radio path set. In the standard of the asynchronous system, Node B informs the RNC of a radio link number (RL) of active cells and a radio link set (RL set) number message to which the RL belongs. For example, if there are three active cells in Node B, there are RL (Radio Link) No. 1, RL No. 2, RL No. 3 for Node B, RL 1 and RL 2 belong to HI RL set 1, and RL 3 is It may be information belonging to HI RL set 2. In the asynchronous system, RL ID and HI RL set numbers are defined as HI RL set ID. In an embodiment of the present invention, a HI radio path set is defined to determine a DL_DPCH slot format for transmitting HI. Therefore, not only the existing RL ID and RL set ID but also information on HI RL set ID created based on the processor for the HSDPA service according to the present invention should be newly defined. The HI RL set ID is for indicating which HI RL set each RL belongs to. Therefore, the information on the radio path that the SRNC 302 should receive from the Node B becomes RL ID, RL set ID, and HI RL set ID.

In step 903, the SRNC 302 receives radio path information received through the NBAP message from the Node B in response to the transmitted radio path information request, and proceeds to step 904. Here, the NBAP message for receiving the radio path information may be, for example, a Radio Link Setup response message. As described above, in the standard, the RL ID and the RL set ID indicate information on the radio path, and in the embodiment of the present invention, the newly added HI RL set ID also indicates radio path information. Meanwhile, as described above, RL set ID refers to an ID of a radio path set in which cells in a Node B soft-combine signals received from a UE, which is different from HI radio path set.

In step 904, the SRNC 302 checks whether the received radio path information of the Node B belongs to the same HI radio path set as the cell currently performing the HSDPA service for the UE 318. If the received node B radio path information is a cell belonging to the same HI radio path set as the cell currently performing the HSDPA service, the SRNC 302 proceeds to step 905. In step 905, the SRNC 302 determines the slot format for transmitting the DL_DPCH slot format HI of the active cell corresponding to the received Node B radio path information and proceeds to step 907. The SRNC 302 proceeds to step 906 when the radio path information of the Node B received in step 904 is not a cell belonging to the same HI radio path set as the cell currently performing the HSDPA service. In step 906, the SRNC 302 determines that the slot format does not transmit the DL_DPCH slot format HI of the active cell corresponding to the received Node B radio path information and proceeds to step 907.

In step 907, the SRNC 302 informs the Node B and the UE 318 of the DL_DPCH slot format determined for the active cells in the active set and ends. Here, the information on the DL_DPCH slot format determined by the SRNC 302 for the active cells is a Node B Application Part (NBAP) which is a signaling message between the SRNC 302 and the Node B as described with reference to FIG. 4. Message to the corresponding Node B. The NBAP message refers to a signaling message between the RNC and the Node B. The NBAP message may select one of the NBAP messages, for example, a Radio Link Setup message, and transmit the determined DL_DPCH slot format. In the standard of the asynchronous system among the messages of the Radio Link Setup, DL_DPCH Slot Format indicates a DPCH slot format for each cell. In step 907, the SRNC 302 transmits the determined DL_DPCH slot format information to the corresponding Node B and simultaneously transmits the determined DL_DPCH slot format information to the UE 318. Here, the determined DL_DPCH slot format information is delivered to the UE 318 through a Radio Resource Control (RRC) message, which is an upper layer signaling message. For example, the SRNC 302 is a cell using a DL_DPCH slot format that transmits HI to the UE 318 through the RRC message, and a cell using a DL_DPCH slot format that does not transmit HI. It can tell you if it is a cell.

Although not illustrated, when the DL_DPCH is transmitted in the manner described with reference to FIGS. 8 and 9, the UE 318 may demodulate the DL_DPCH signal in the same manner as described with reference to FIG. 7.

10 is a block diagram showing an internal configuration of a base station performing a function in an embodiment of the present invention.

Referring to FIG. 10, data 1001 to be transmitted through a dedicated physical channel is channel coded by the encoder 1002 and rate matched by the number of bits to be transmitted in the physical channel by the rate matching unit 1003. The HI 1005, which is an HS-DSCH indicator, controls the switch 1004 in the controller 1006 to turn on the switch so that HI is transmitted if the HI is a slot format in which the HI is transmitted, and the HI is input to the multiplexer 1010. Put it in. If the slot format does not transmit HI, the controller turns off the switch so that HI is not input to the multiplexer 1010. As described above, the control unit adjusts whether or not to insert the HI field according to the DPCH transmission format of the cell informed by the RNC. The output of the rate matching unit 1003, the output of the switch 1004, the TFCI 1007, the Pilot 1008, and the TPC 1009 are applied to the multiplexer 1010 and output as one bit stream. At this time, even in the case of multiplexing, in the case of a slot format in which the control unit 1006 transmits HI, the HI field is inserted and thus, for example, another TFCI or pilot field should be reduced. That is, the controller 1006 controls the multiplexer 1010 according to the DPCH slot format to adjust the size of each data field.

The output bitstream of the multiplexer 1010 is converted into two bit streams by 1011, and the spreader 1012 spreads the two bit streams using the same channelization code, so that signals with different channelization codes are used. You have orthogonality. In this case, the two bit streams I and Q signals of the spreader output are output as one complex stream by the multiplier 1013 and the adder 1014. The complex stream output is multiplied by the complex mixing code on a chip-by-chip basis by the mixer 1015 to distinguish it from a signal using a different mixing code. The output of the mixer 1015 is again multiplied by the channel gain by the multiplier 1016. Meanwhile, FIG. 10 also shows a transmission apparatus for the SHCCH. The HS-DSCH control information 1017 is converted into two bit streams by 1018, spread by the spreader 1019, and again by 1020 and 1021. Two bit streams are converted into one complex stream. The complex output of 1021 is multiplied by the multiplier 1022 with the complex mixed code on a chip-by-chip basis and then multiplied by the channel gain in the multiplier 1023. The forward dedicated physical channel output of 1016 and SHCCH output of 1023 are added in summer 1024, modulated in modulator 1025, converted into RF band signals by RF unit 1026, and then transmitted via antenna 1027.

11 is a block diagram showing an internal configuration of a user terminal for performing a function in an embodiment of the present invention.

Referring to FIG. 11, the signal received by the antenna 1101 is converted into a baseband signal by the RF unit 1102, and the demodulator 1103 demodulates the signal as opposed to the modulator 1125 of FIG. 11. Thereafter, the terminal allocates signals of various paths from various cells to different fingers in the finger allocator 1104. Here, priority is assigned to the finger regardless of the DPCH slot format for each path. The reason for this is that each finger has two circuits capable of demodulating both DPCHs having a slot format that does not transmit HI and a slot format that transmits HI. Assuming N fingers, the signal from each active cell is assigned to finger 1 (1105), finger 2 (1111), finger N (1117), and the like, and then the controller 1127 provides information on which finger each cell is assigned to. To). Meanwhile, since the UE receives information on the radio path through higher layer signaling from the BS, the UE knows the DPCH slot format of the cell. Thus, the controller 1127 sets the switches 1106, 1112, and 1118 to demodulate fingers according to the slot format by using information on which cell signal is assigned to which finger and the slot format of each cell. For example, if the DPCH slot format of the cell assigned to the first finger is a slot format for transmitting HI, the controller adjusts the switch 1106 so that the output of the finger 1105 is an input of the demultiplexer 1107. If the slot format is a slot format that does not transmit HI, the controller 1127 adjusts the switch 1106 so that the output of the finger 1105 becomes an input of 1109.

If the slot format of the cell assigned to the finger 1 is a slot format for transmitting HI, the demultiplexer 1107 uses Data1, TPC, TFCI, Data2, and Pilot 1109 defined in Release-99 different from the HI information 1108. Distinguish If the slot format of the cell allocated to finger 1 is a slot format that does not transmit HI, Data1, TPC, TFCI, Data2, and Pilot are extracted at 1110. Similarly, the controller 1127 adjusts the switch 1112 according to the slot format. If the slot format of the cell allocated to the finger 2 is a slot format for transmitting HI, the demultiplexer 1113 uses Data1, TPC, TFCI, Data2, and Pilot 1115 defined in Release-99 different from the HI information 1114. Distinguish If the slot format of the cell allocated to finger 2 is a slot format that does not transmit HI, Data1, TPC, TFCI, Data2, and Pilot are extracted at 1116. For the last finger N, the controller 1127 adjusts the switch 1118 according to the slot format. If the slot format of the cell allocated to the finger N is a slot format for transmitting HI, the demultiplexer 1119 uses Data1, TPC, TFCI, Data2, and Pilot 1121 defined in Release-99 different from the HI information 1120. Distinguish If the slot format of the cell allocated to finger 2 is a slot format that does not transmit HI, Data1, TPC, TFCI, Data2, and Pilot are extracted at 1122.

As described above, the controller 1127 distinguishes HI and Release-99 data or HI-defined data according to the DPCH slot format of the cell allocated to the finger. Then, if the finger is a slot format for transmitting HI, HI information obtained by sending HI information extracted to the HI wireless path combiner 1123 to perform soft combining between HIs is obtained. Data1, TPC, TFCI, Data2, and Pilots defined in Release-99, except HI, are sent to the radio path combiner 1124 to obtain Data1, TPC, TFCI, and Data2 soft combining (1126). In this case, a pilot signal is used by the radio path combiner 1124 to estimate downlink channels from the base station for radio path combining. In summary, if the slot format of the cell assigned to the finger is a slot format for transmitting HI, the terminal may have a soft combining effect between HIs, and Data1, TPC, TFCI, Data2, and Pilot other than HI may be used regardless of the slot format. It has a soft combining effect for all radio paths. On the other hand, in the above, each finger could support both the slot format for transmitting HI and the slot format for not transmitting HI. If the number of cells having a slot format for transmitting HI is possible up to M, the structure can support both slot formats for only M fingers, and only the slot formats without transmitting HI can be supported for the remaining NM fingers. You can also reduce hardware complexity.

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 provides a dedicated physical channel for active cells of a user terminal when a user terminal currently receiving a high speed forward packet access service is located in a soft handover area in a communication system using a fast forward packet access scheme. By variably operating the slot format, the multipath diversity effect on HI and other data is increased. In addition, by varying the slot format of the dedicated physical channel for the active cells of the user terminal has the advantage of improving the reliability of the high-speed forward packet access service received by the user terminal.

Claims (8)

A forward slotted physical channel having a first slot format including at least a fast forward common channel indicator field indicating presence or absence of fast forward packet access service data and a second slot format not including the fast forward common channel indicator field; A method for determining a slot format of a forward dedicated physical channel in a communication system, Checking whether an active cell is added to the user terminal when the user terminal currently receiving the fast forward packet access service is located in the soft handover area; Determining a slot format of a forward dedicated physical channel of the added active cell as the second slot format when the active cell is added as a result of the checking; And transmitting the determined slot format for the dedicated physical channel of the active cell to the user terminal and the corresponding base station. A forward slotted physical channel having a first slot format including at least a fast forward common channel indicator field indicating presence or absence of fast forward packet access service data and a second slot format not including the fast forward common channel indicator field; In the method of determining the slot format of the forward dedicated physical channel in the communication system, Checking whether an active cell is added to the user terminal when the user terminal currently receiving the fast forward packet access service is located in the soft handover area; If the active cell is added as a result of the check, checking whether the user terminal exists in the same fast forward common channel indicator radio path set as the cell receiving the fast forward packet access service; If the check result indicates that the active cell is present in the same fast forward common channel indicator radio path set, the slot format of the forward dedicated physical channel of the active cell is determined as the first slot format, and the active cell is the same fast forward common. Determining a slot format of a forward dedicated physical channel of the active cell as the second slot format if the active cell does not support the fast forward packet access service when not present in the channel indicator radio path set. The method characterized in that. The method of claim 2, And transmitting the slot format for the determined physical channel of the active cell to the user terminal and the corresponding base station. A forward slotted physical channel having a first slot format including at least a fast forward common channel indicator field indicating presence or absence of fast forward packet access service data and a second slot format not including the fast forward common channel indicator field; A method for determining a slot format of a forward dedicated physical channel in a communication system, Checking whether an active cell is added to the user terminal when the user terminal currently receiving the fast forward packet access service is located in the soft handover area; If the active cell is added as a result of the check, checking whether the user terminal exists in the same fast forward common channel indicator radio path set as the cell receiving the fast forward packet access service; If the check result indicates that the active cell is present in the same fast forward common channel indicator radio path set, the slot format of the forward dedicated physical channel of the active cell is determined as the first slot format, and the active cell is the same fast forward common. And determining a slot format of a forward dedicated physical channel of the active cell as the second slot format when it is not present in the channel indicator radio path set. The method of claim 4, wherein And transmitting the slot format for the determined physical channel of the active cell to the user terminal and the corresponding base station. A forward slotted physical channel having a first slot format including at least a fast forward common channel indicator field indicating presence or absence of fast forward packet access service data and a second slot format not including the fast forward common channel indicator field; A method for determining a slot format of a forward dedicated physical channel in a communication system, Checking whether an active cell is added to the user terminal when the user terminal currently receiving the fast forward packet access service is located in the soft handover area; Requesting radio path information from a base station of the active cell when the active cell is added as a result of the inspection; Checking whether the active cell exists in the same fast forward common channel indicator radio path set as the cell in which the user terminal receives the fast forward packet access service by using the radio path information received from the base station according to the radio path information request. and, If the check result indicates that the active cell is present in the same fast forward common channel indicator radio path set, the slot format of the forward dedicated physical channel of the active cell is determined as the first slot format, and the active cell is the same fast forward common. And determining a slot format of a forward dedicated physical channel of the active cell as the second slot format when it is not present in the channel indicator radio path set. The method of claim 6, And transmitting the slot format for the determined physical channel of the active cell to the user terminal and the corresponding base station. A forward slotted physical channel having a first slot format including at least a fast forward common channel indicator field indicating presence or absence of fast forward packet access service data and a second slot format not including the fast forward common channel indicator field; An apparatus for determining a slot format of a forward dedicated physical channel in a communication system, A receiver receiving slot format information of a forward dedicated physical channel received from a base station controller and determining whether to transmit the fast forward common channel indicator according to the received slot format structure of the forward dedicated physical channel; If the receiver determines not to transmit the fast forward common channel indicator, the slot format of the forward dedicated physical channel is set to the second slot format, and if the receiver determines to transmit the fast forward common channel indicator, the forward only And a transmitter for determining a slot format of a physical channel as the first slot format and transmitting the packet through the forward dedicated channel.