KR20060081261A - Method for performing layer 1 combining of e-rgch in soft handover region in mobile telecommunication system - Google Patents

Abstract

The present invention relates to a mobile communication system for transmitting packet data through an uplink, and more particularly, to a method of first-layer combining a forward signal transmitted from a plurality of cells when a user terminal is located in a soft handover area. In the EUDCH, cells to perform 1-layer combining for an arbitrary cell may be different from when the cell operates as a main cell for an arbitrary terminal and when not, where the UE is to perform 1-layer combining according to circumstances. We present a method for recognizing cells to perform.

WCDMA, UPLINK PACKET DATA SERVICE, E-DCH, EUDCH, EDCH active set, E-RGCH

Description

METHODE FOR PERFORMING LAYER 1 COMBINING OF E-RGCH IN SOFT HANDOVER REGION IN MOBILE TELECOMMUNICATION SYSTEM}             

1A is a diagram illustrating a change in uplink radio resources of a base station when general base station control scheduling is not used.

1B is a diagram illustrating a change of uplink radio resources of a base station when using general base station control scheduling.

2 is a diagram illustrating a user terminal and a base station for performing general uplink packet transmission.

3 is a diagram illustrating information transmitted and received between a user terminal and a base station to perform a general uplink packet transmission.

4 is a diagram illustrating the structure of a soft handover area according to the present invention;

5 shows a first embodiment of the present invention;

FIG. 6 is a diagram illustrating a flow of control information between a terminal and an RNC and operations of the terminal and the RNC when the RNC determines a primary cell in the first embodiment of the present invention.

FIG. 7 illustrates a flow of control information between a terminal and an RNC and operations of the terminal and the RNC when the terminal determines a primary cell in the first embodiment of the present invention.

8 is a flowchart illustrating the operation of a user terminal according to the first embodiment of the present invention.

Fig. 9 is a view for schematically explaining a second embodiment of the present invention.

FIG. 10 illustrates a flow of control information between a terminal and an RNC and operations of the terminal and the RNC when the RNC determines a main cell in the second embodiment of the present invention.

FIG. 11 is a diagram illustrating a flow of control information between a terminal and an RNC and operations of the terminal and the RNC when the terminal determines a primary cell in the second embodiment of the present invention.

12 is a flowchart illustrating an operation of a user terminal according to a second embodiment of the present invention.

The present invention relates to a mobile communication system for transmitting packet data through uplink, and more particularly, to a method for efficiently performing 1-layer combining in a soft handover region.

Asynchronous wideband code division multiple access (WCDMA) communication systems employ an enhanced uplink dedicated channel (hereinafter referred to as "E-DCH" or "EUDCH"). use. The E-DCH is a channel proposed to improve the performance of packet transmission in reverse communication in an asynchronous code division multiple access communication system.                         

The mobile communication system supporting the E-DCH maximizes the efficiency of uplink transmission by using a Node B-controlled scheduling technique and a hybrid automatic retransmission request (HARQ) technique. The base station scheduling technique is a base station (Node B) to report the channel status and buffer status of the user equipment (User Equipment (UE)), and to control the reverse transmission of the UE based on the received information. The base station allows efficient use of limited uplink transmission resources by allowing large amounts of data transmission to UEs in good channel conditions and minimizing the amount of data transmission for UEs in poor channel conditions. The HARQ technique increases the transmission success rate compared to the transmission output by executing HARQ between the UE and the base station. Through the HARQ technique, the base station performs soft combining with the retransmitted data block without discarding the data block in which an error occurs during transmission, thereby increasing the probability of success of receiving the data block.

In the uplink, orthogonality is not maintained between signals transmitted by a plurality of user terminals (UEs), thus acting as interference signals. Therefore, as the number of uplink signals received by the base station increases, the amount of interference signals for the uplink signals transmitted by a specific UE also increases. Therefore, as the amount of the interference signal for the uplink signal transmitted by a specific UE increases, the reception performance of the base station is degraded. This limits the amount of uplink signals that the base station can receive while guaranteeing overall reception performance. The radio resource of the base station is represented by Equation 1 below.

RoT = Io / No

Io is the total received broadband power spectral density of the base station, and No represents the thermal noise power spectral density of the base station. Accordingly, the ROT becomes a radio resource that the base station can allocate for the E-DCH packet data service in the uplink.

1A and 1B show a change in uplink radio resources that can be allocated by a base station.

As shown in FIGS. 1A and 1B. The uplink radio resource that can be allocated by the base station can be represented by the sum of inter-cell interference 101 (113), voice traffic (Voice traffic 102, 112), and E-DCH packet traffic (103, 111). .

First, FIG. 1A illustrates a change in the total ROT when the base station scheduling is not used. In this case, since scheduling is not performed for E-DCH packet traffic, when a plurality of UEs simultaneously transmit the packet data using a high data rate, the total ROT is higher than the target ROT 104. Level (105, 106, 107). In this case, the reception performance of the uplink signal is degraded.

Next, Figure 1b shows the change in the total ROT when using base station scheduling. In this case, the base station prevents the plurality of UEs from simultaneously transmitting the packet data using a high data rate. That is, the base station scheduling prevents the total ROT from increasing above the target ROT 115 by allowing low data rates for other UEs when allowing a high data rate for a particular UE. Specifically, as the data rate of a specific UE increases, the received power that the base station receives from the UE increases. Therefore, the ROT 114 of the UE takes a large part of the total ROT. On the other hand, when the data rate of the UE decreases, the reception power received by the base station from the UE decreases. Thus, the ROT 116 of the UE takes up a small portion of the total ROT. The base station performs base station scheduling for the E-DCH packet data in consideration of the relationship between the data rate and radio resources and the data rate requested by the UE.

The base station notifies whether E-DCH data transmission is possible for each UE by using request data rate or channel state information of UEs using the E-DCH or schedules the base station to adjust the E-DCH data rate. Do this. The base station scheduling may be regarded as an operation in which the base station distributes RoT to each terminal based on channel conditions and buffer states of terminals performing E-DCH communication.

2 is a diagram illustrating a user terminal and a base station for performing uplink packet transmission.

Referring to FIG. 2, UEs 201, 202, 203, and 204 are transmitting uplink packet data with transmission power of different reverse channels according to the distance from the base station 200. The UE 204 farthest from the base station 200 transmits packet data at the transmit power 224 of the highest reverse channel, and the UE 202 closest from the base station 200 has the lowest reverse direction. The packet data is transmitted at the transmit power 222 of the channel. The base station 200 may schedule the data to be inversely proportional to the strength of the transmit power of the reverse channel in order to improve the performance of the mobile communication system while reducing the ICI for other cells while maintaining the total ROT. Therefore, the base station 200 allocates a small transmission resource to the UE having the highest transmission power of the reverse channel, and allocates many transmission resources to the UE having the lowest transmission power of the reverse channel to efficiently maintain the total ROT. .

3 illustrates an operation in which a UE is allocated a transmission resource for transmitting E-DCH packet data from a base station and transmits the packet data using the allocated transmission resource.

Referring to FIG. 3, in step 303, an E-DCH is configured between the base station 300, the cell 301, and the UE 302. At this time, the cell 301 provides substantial radio resources, and the base station 300 controls the cell 301. A plurality of cells may be connected to one base station, and includes a process of transmitting and receiving messages through a dedicated transport channel between the cell 301 and the terminal 302.

The UE 302 having configured the E-DCH in step 304 transmits information on necessary transmission resources and information on uplink channel conditions to the base station 300. The information includes uplink transmission power transmitted by the UE 302, transmission power margin of the UE 302, buffer status information of the terminal, and the like.

The base station 300 receiving the information estimates a forward channel situation by comparing the transmission power of the uplink channel with the actual measured reception power. That is, if the difference between the uplink transmit power and the uplink receive power is small, the reverse channel situation is good. If the difference between the transmit power and the receive power is large, the reverse channel situation is poor. When the UE transmits a transmit power margin to estimate an uplink channel condition, the base station 300 estimates the uplink transmit power by subtracting the transmit power margin from the maximum possible transmit power of a UE that is already known. do. The base station 300 uses the estimated channel status of the UE and buffer status information of the UE 302 to determine possible transmission resources for an uplink packet channel of the UE.

The determined transmission resource is notified to the UE 302 in step 304. The transmission resource may be a size of data that can be transmitted, that is, a transmission rate, or a transmission output that can be used.

Notification of the transmission resource occurs in two ways. First, the base station can inform the absolute value of the data rate (or radio resource) that can be used by the terminal through ECH-ABCH (EDCH-Absolute Grant Channel) of the cell 301 where the terminal is located. The E-AGCH is a channel set for each terminal and is set in step 303. In addition, the base station may inform the relative value of the data rate (or radio resource) that can be used by the terminal through an EDCH-Relative Grant Channel (E-RGCH) of the cell 301 where the terminal is located. The relative value is a relative value with respect to the data rate currently being used. For example, the relative value may be informed via the E-RGCH of a dataator that is one step higher, one step lower, or the same as the current data rate. The E-RGCH may adjust data rates for one terminal and may adjust data rates for multiple terminals. For convenience of explanation, the former is referred to as the RG control mode as dedicated, and the latter as the RG control mode as common.

When the RG control mode is dedicate, the E-RGCH is set exclusively for the terminal. That is, one E-RGCH is allocated to one terminal. On the other hand, when the RG control mode is common, a plurality of UEs share one E-RGCH. In general, when the UE is located in the soft handover area, the RG control mode between the UE and the primary cell is dedicate, and the RG control mode between the UE and the non-main cell can be both dedicate and common.

The UE 302 determines the size of packet data to be transmitted to the informed transmission resource, and transmits the determined size data to the base station 300 in step 306. In this case, one unit of the packet data transmitted through the E-DCH is called a Media Access Control-enhanced Protocol Data Unit (MAC-e PDU), and a channel through which the MAC-e PDU is transmitted is called an E-DPDCH (EDCH-Dedicate). Physical Data Channel).

EDCH supports the soft handover of the terminal. This means that when the terminal enters the soft handover area, a plurality of cells process the E-DPDCH of the terminal, and the terminal receives the E-RGCH from the plurality of cells. When E-RGCH is received from multiple cells, one-layer combining may be performed on the E-RGCHs received from specific cells, thereby increasing the reliability of the E-RGCH signal.

Accordingly, in order to increase the reliability of the E-RGCH signal, the UE needs to determine which cells of the E-RGCHs to perform 1-layer combining based on control information provided by the RNC.

Accordingly, an object of the present invention, which was devised to solve the problems of the prior art operating as described above, is to combine the E-RGCH into the first layer when the UE is located in the soft handover area in a mobile communication system supporting uplink. It is to provide a method for determining cells to be inched.

Another object of the present invention, if any cell is the primary cell, to provide an identifier of the primary cell indicating this to the terminal,

Another object of the present invention is to provide a terminal with a primary RG-RLS identifier and a secondary RG-RLS identifier indicating whether any cell is included in the primary RG-RLS or the secondary RG-RLS.

It is still another object of the present invention to provide a method of performing a layer 1 combine on an E-RGCH of a primary cell when the primary RG-RLS identifiers are the same when cells belonging to the same node ratio belong to the primary RG-RLS. .

It is still another object of the present invention to provide a method of performing a layer 1 combine on an E-RGCH of a secondary cell if the secondary RG-RLS identifiers are the same when cells belonging to the same node ratio do not belong to the primary RG-RLS. It is.

An embodiment of the present invention, which was created to achieve the above object, comprises a base station consisting of a plurality of cells, and a radio network controller for managing radio resources of the base stations and cells. In a mobile communication system for transmitting packet data through an E-DCH, when the radio network controller determines a primary cell in a soft handover region, a method of performing layer 1 combining,

Setting an 'E-DCH active set' which is a set of cells processing the E-DCH according to a channel condition of a cell;

Configuration information when the primary RG-RLS (Serving Relative Grant-Radio Link Set) is configured for the cells among the cells included in the E-DCH active set and configuration information when the secondary RG-RLS is configured It characterized in that it comprises a process of transmitting to.

Another embodiment of the present invention comprises a base station consisting of a plurality of cells, and a radio network controller for managing radio resources of the base stations and cells, and transmits packet data through an uplink channel (E-DCH) In the mobile communication system, when the terminal communicating with the radio network controller in the soft handover area determines the primary cell, a method for performing layer 1 combining,

Receiving 'E-DCH active set' configuration information, which is a set of cells processing an E-DCH, from the radio network controller;

Among the cells belonging to the E-DCH active set, an EDCH-Relative Grant Channel (E-RGCH) coming from a predetermined primary cell and a 'primary RG-RLS identifier' equal to the 'primary RG-RLS identifier' of the determined primary cell Performing 'first layer combining' on the E-RGCH coming from cells having

E-transmitted from cells having the same 'secondary RG-RLS identifier' after constructing the 'secondary RG-RLS' from cells having the same 'secondary RG-RLS identifier' among cells not included in the primary RG-RLS. RGCHs may be configured to include 'first layer combining'.

Another embodiment of the present invention comprises a base station consisting of a plurality of cells, and a radio network controller for managing radio resources of the base stations and cells, and transmits packet data through an uplink channel (E-DCH) In the mobile communication system, when the terminal communicating with the radio network controller in the soft handover area determines the primary cell, a method for performing layer 1 combining,

Receiving 'E-DCH active set' configuration information, which is a set of cells processing an E-DCH, from the radio network controller;

Among the cells belonging to the E-DCH active set, an EDCH-Relative Grant Channel (E-RGCH) coming from a predetermined primary cell and a 'primary RG-RLS identifier' equal to the 'primary RG-RLS identifier' of the determined primary cell Performing 'first layer combining' on the E-RGCH coming from cells having

E-RGCH transmitted in cells not included in the primary RG-RLS and cells having the same 'primary RG-RLS identifier' among cells whose relative tolerance control mode of cells not included in the primary RG-RLS is 'dedicated' It characterized in that it comprises a process of performing a 'first layer combining' for.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating principle of the preferred embodiment of the present invention. Like reference numerals are used to designate like elements even though they are shown in different drawings, and detailed descriptions of related well-known functions or configurations are not required to describe the present invention. If it is determined that it can be blurred, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

A main feature of the present invention described below is to transmit / receive control information for the uplink packet data service as part of uplink packet data in a mobile communication system supporting the uplink packet data service. In the following description, the uplink packet data service will use E-DCH (Enhanced Uplink Dedicated CHannel) of UMTS (Universal Mobile Telecommunication Service), which is one of the third generation mobile communication. The present invention is not limited to the above systems and standards, but rather should be understood as all kinds of communication systems to which the following description is applicable.

The UMTS Terrestrial Radio Access Network (hereinafter referred to as "UTRAN") of the UMTS system includes a base station (Node B) consisting of a plurality of cells and a radio network controller managing radio resources of the base stations and cells ( Radio Network Controller (hereinafter referred to as RNC).

Since the present invention relates in particular to the operation of a terminal in a soft handover area, FIG. 4 is a diagram illustrating a structure of a soft handover area according to a preferred embodiment of the present invention. Here, EDCH supports soft handover, which means that if the UE is located in the soft handover region, the backward signal transmitted by the UE is processed by the plurality of cells to obtain macro diversity gain. . The set of cells processing the reverse signal related to the EDCH is called an 'E-DCH active set'.

Referring to FIG. 4, an E-DCH active set for an arbitrary terminal 540 is transmitted to cell 1 515, cell 2 520, cell 3 525, cell 4 530, and cell 5 535. Consists of. At this time, cell 1 515 and cell 2 520 are connected to the same Node B 505, and cell 3 525 and cell 4 530 are connected to the same Node B 510.

The cells 1 to 5 (515 to 535) process the E-DPDCH transmitted by the terminal 540. This means that the terminal uses RoTs of the cells 1 to 5 (515 to 535), and that the RoT situation of the related cells should be considered in scheduling for the terminal 540.

When the terminal 540 is located in the soft handover area, that is, when a plurality of cells are involved in the scheduling of the terminal 540, scheduling is performed as follows.

Among a plurality of cells 515 to 535 belonging to the E-DCH active set, one cell serves as a serving cell according to a predetermined criterion. The predetermined criterion may be a channel condition or the like. The primary cell provides an Absolute Grant (AG) to the UE and provides a dedicate relative grant (RG). AG is the absolute value of the data rate (or radio resource) that the terminal can use as described above. The dedicate RG means a relative grant (RG) that affects only one UE. Therefore, E-AGCH and E-RGCH are configured between the main cell and the terminal.

Only RG is transmitted from cells other than the main cell, so that the E-RGCHs 545 to 575 are configured between the cells and the terminal 540. For example, if cell 1 515 is the main cell, one E-RGCH 560 is configured between the terminal 540 and the cell 2 520, and the E-RGCH 560 is formed between the terminal 540 and the cell 3 525. One RGCH 565 is configured, one E-RGCH 570 is configured between the terminal 540 and the cell 4 530, and the E-RGCH 575 is between the terminal 540 and the cell 5 575. Is composed one. Of course, one E-RGCH 545 is configured between the primary cell Cell 1 515 and the terminal 540.

As described above, the RG is transmitted through the E-RGCH, and the RG contains three pieces of information consisting of 'UP', 'Hold' and 'Down'. 'Up' indicates that the data rate is allowed one step higher than the data rate currently in use, and 'Hold' indicates that the data rate is currently being used. 'Down' indicates that the data rate is allowed one step lower than the current data rate.

The Node B transmits the RG through the E-RGCH of each cell according to the RoT situation for each cell. The terminal may receive several RGs at the same time, and when each RG has a conflicting information with each other, the terminal gives priority to Down / Hold / Up. That is, if one cell requires Down, even if all the other cells require Up, it follows the Down request.

Accordingly, in determining the RG to be transmitted for each cell managed by the Node B, even if it is necessary to transmit different RGs in the cell situation, the Node B may transmit the same RG. For example, if the RoT situation in cell 1 515 is good and an Up command is sent, and the Down command is sent because the RoT situation in cell 2 520 is poor, the Up command has no meaning, so cell 1 (515) The down command can also be sent through the E-RGCH.

If the same RG is transmitted through the E-RGCH of cells connected to the same Node B as described above, the reception performance of the E-RGCH can be improved by performing layer 1 combining on the E-RGCH of the cells to the UE. To this end, the RNC must notify the UE in advance of the set of cells to perform 1-layer combining in the EDCH active set configuration process. At this time, depending on whether a specific cell is included in the main RG-RLS (Serving Relative Grant-Radio Link Set), the set of cells to perform 1-layer combining may also vary. The primary RG-RLS is a set of cells to perform 1 layer combining with the E-RGCH transmitted from the primary cell.

 Any cell may be different from the case where it is included in the main RG-RLS, and the RG control mode used when not included. For example, the cell 1 515 may be set such that the RG control mode is 'dedicate' when included in the main RG-RLS, but the RG control mode is 'common' when not included in the main RG-RLS. In such a situation, when the cell 1 515 is included in the primary RG-RLS, the cell 1 515 may perform 1-layer combining with the E-RGCH of the cell 2 520 connected to the same Node B. When not included in the RG-RLS, one-layer combining with the E-RGCH of another cell should not be performed.

In addition, the RNC may set a different set of cells to perform 1-layer combining when an arbitrary cell is included in the primary RG-RLS and when it is not included. For example, suppose that the RNC is to configure the E-RGCHs of each cell to be 1-layer combine as follows.

The E-RGCH 545 of cell 1 515 combines one layer with the E-RGCH 560 of cell 2 520 if it belongs to the primary RG-RLS, and the one layer combine if it does not belong to the primary RG-RLS. I never do that. The E-RGCH 560 of cell 2 520 combines with the E-RGCH 545 of cell 1 515 one layer if it belongs to the primary RG-RLS, and the one layer combine if it does not belong to the main RG-RLS. I never do that.

E-RGCH 565 of cell 3 525 is one layer combine with E-RGCH 570 of cell 4 530 if it belongs to primary RG-RLS, and cell 4 (if it does not belong to primary RG-RLS). Combine one layer with the E-RGCH (530). E-RGCH 570 of cell 4 530 is one layer combine with E-RGCH 565 of cell 3 525 if it belongs to primary RG-RLS, and cell 3 (if it does not belong to primary RG-RLS). Combine with E-RGCH of 525).

 If the E-RGCH 575 of cell 5 (535) belongs to the main RG-RLS, it does not combine 1 layer. Note If it does not belong to RG-RLS, it does not combine 1 layer.

As described above, when cell 1 515 and cell 2 520 are connected to the same Node B, but does not perform a 1-layer combine except the main RG-RLS, an example of cell 1 515 may be used. E-RGCH can occur when it is set to operate in 'common' mode if it does not belong to the main RG-RLS. That is, the E-RGCH operating in the 'common' mode is not 1 layer combined with the E-RGCH of another cell. On the other hand, if the E-RGCH of cell 3 525 and the E-RGCH of cell 4 530 both operate in the 'dedicate' mode, the E-RGCHs of the cells are layer 1 with each other even if they do not belong to the main RG-RLS. Can be combined.

As described above, whether or not the 1-layer combine of the E-RGCH may be different depending on whether the corresponding cell belongs to the main RG-RLS, so the RNC needs to combine the E-RGCHs of which cell to the UE in 1 layer. You have to tell them.

Hereinafter, according to the first embodiment of the present invention, when a cell belongs to a primary RG-RLS with respect to one cell, a primary RG-RLS ID Serving Rate Grant Radio Link Set ID (ID) indicating this, and the cell In this paper, a method of separately assigning a non-primary RG-RLS ID, which is an identifier indicating a non-primary RG-RLS, is proposed.

5 is a diagram briefly showing a first embodiment of the present invention.

Referring to FIG. 5, when the cell 1 615 and the cell 2 620 are combined in one layer when they are the primary RG-RLS, the same primary RG-RLS ID 'S1' is allocated. Since the cell 1 615 and the cell 2 620 are not combined in a single layer when they are not the main RG-RLS, different sub RG-RLS IDs of 'N1' and 'N2' are allocated.

Cell 3 625 and cell 4 630 are assigned the same primary RG-RLS ID of 'S2' because they are combined one layer when they are primary RG-RLS. Since the cell 3 625 and the cell 4 630 are combined by one layer even when they are not the main RG-RLS, the same secondary RG-RLS ID of 'N3' is allocated.

In any case, since cell 5 635 has no first layer combined cell, cell 5 635 has a 'S4' which is different from the primary RG-RLS ID and the secondary RG-RLS ID of all other cells with the primary RG-RLS ID and the secondary RG-RLS ID. 'N4' is assigned. S1, S2, S4, N1, N2, N3, and N4 are arbitrary integers.

The terminal 640 recognizes the primary RG-RLS ID and the secondary RG-RLS ID allocated to each cell, and determines whether to combine the first RG-RLS ID with respect to the primary RG-RLS ID of the cells. And, for the cells other than the primary RG-RLS, it is determined whether the first layer is combined by referring to the secondary RG-RLS IDs of the cells.

For example, if the serving cell is the cell 1 615, the cell 2 620 having the same primary RG-RLS ID as the primary RG-RLS ID of the primary cell 1 615 and 'S1' and The primary cell 1 615 configures the primary RG-RLS, and the terminal 640 combines the E-RGCHs of the cells 615 and 620 corresponding to the primary RG-RLS by one layer.

The UE 640 checks secondary RG-RLS IDs of remaining cells that do not belong to the primary RG-RLS among the cells of the E-DCH active set. The sub-RG-RLS is configured of cells having the same sub-RG-RLS ID and performs one-layer combine. That is, cells 3 (625), cells 4 (630), and cells 5 (635) are cells that do not belong to the primary RG-RLS, and the secondary RG-RLS IDs of cells 3 (625) and cells 4 (630) are Since they are the same as 'N3', the cells 625 and 630 constitute one sub-RG-RLS, and the E-RGCHs of the cells 625 and 630 are combined by one layer.

6 is a diagram illustrating a control message exchange operation between an RNC and a terminal according to the first embodiment of the present invention.

Referring to FIG. 6, the terminal 705 reports the measurement result of the channel condition of the neighbor cell to the RNC 710 periodically or when a specific condition is satisfied. The RNC 710 sets an E-DCH active set based on the measurement result.

For example, the E-DCH active set may consist of cells whose channel condition is better than a certain criterion. The cells belonging to the E-DCH active set process the E-DPDCH transmitted by the terminal 705 and transmit an E-RGCH signal to the terminal 705. That is, the cells may adjust the E-DPDCH transmission rate of the UE through an ECH-Relative Grant Channel (E-RGCH). In this case, the E-RGCH signal is given as a common RG for controlling transmission rates of a plurality of terminals, or as a dedicate RG for controlling transmission rates of one terminal.

It is determined by the RNC 710 in which mode a particular terminal is scheduled in a particular cell. For example, if the terminal 705 is transmitting high-speed data, the transmission rate of the terminal 705 is preferably controlled by the dedicate RG, and the terminal transmitting the low-speed data is controlled by the common RG. desirable.

In step 715, the RNC 710 determines cells to be included in the E-DCH active set, determines configuration information of the E-DCH active set, and transmits the same to the terminal 705. The E-DCH active set configuration information includes identifiers of cells included in the E-DCH active set, primary RG-RLS configuration information and secondary RG-RLS configuration information for each cell. The primary RG-RLS configuration information includes channel information of the E-RGCH and primary RG-RLS ID. The secondary RG-RLS configuration information includes channel information of the E-RGCH, secondary RG-RLS ID, and RG control mode information (dedicate or common).

When determining the primary RG-RLS ID and the secondary RG-RLS ID of the cell, the RNC 710 determines that the following conditions are satisfied. That is, the primary RG-RLS ID for any 'cell x' should be the same as the primary RG-RLS ID of cells to perform 1-layer combining on the E-RGCH when the cell x is the primary cell.

In general, since E-RGCH of cells belonging to the same Node B is capable of layer 1 combining, the same primary RG-RLS ID is allocated to cells belonging to the same Node B. FIG. However, if the RNC 710 wants to schedule some of the cells belonging to the same Node B individually, it may assign different primary RG-RLS IDs to the cells belonging to the same Node B as well. For example, if a control block exists for each cell in Node B, layer combining should not be applied to the E-RGCHs of the cells.

The secondary RG-RLS ID for any 'cell y' must be the same as the secondary RG-RLS ID of the cells that will perform 1 layer combining for the E-RGCH when cell y is not included in the primary RG-RLS. .

In general, E-RGCH of cells belonging to the same Node B is capable of 1-layer combining, but when the cell is not included in the primary RG-RLS, the RG control mode may be set to common, in which case it is included in the same Node B. Even if the cells are not used, one-layer combining should not be performed.

When the RG control mode is dedicate, since the RG transmitted through the E-RGCH affects only one UE, it is possible to set the RG of two different cells to the same value. However, when the RG control mode is common, the RG transmitted through the E-RGCH affects multiple terminals, and since the RGs of two different cells are different from each other, the RGs in the common mode are different. It is not possible to set it to the same value. Therefore, even if two cells are connected to one Node B and physically capable of transmitting the same RG through the E-RGCH, even if one of the two cells operates in the common mode, the same RG can always be transmitted. As a result, one-tier combining should not be performed. For reference, cells belonging to the main RG-RLS are always defined to operate in dedicate mode. This is because the common mode is proposed for use in secondary RG-RLS.

Upon receiving the E-DCH active set configuration information, the terminal 705 configures an E-DCH active set according to the E-DCH active set configuration information in step 720 and transmits a response message to the RNC 710. . In step 725, the RNC 710 transmits an identifier of a cell that will serve as a primary cell in the E-DCH active set to the terminal 705. In this case, the identifier of the primary cell may be given to the UE 705 without being included in step 725 and included in the E-DCH active set configuration information of step 715.

In step 730, the terminal 705 receiving the primary RG-RLS ID of the cell corresponding to the identifier of the primary cell transmits a response message to the RNC 710. In step 735, the terminal 705 configures the main RG-RLS using the received 'main RG-RLS ID of the main cell'. That is, the cells having the same primary RG-RLS ID as the 'main RG-RLS ID of the main cell' and the main RG-RLS are configured as the main cells, and the E-RGCHs transmitted from the cells of the main RG-RLS. Layer 1 combining is performed.

In step 740, the terminal 705 selects cells to perform 1-layer combining by checking secondary RG-RLS IDs of cells not included in the primary RG-RLS. That is, among the cells not included in the primary RG-RLS, one layer combining is performed on cells having the same secondary RG-RLS ID.

In FIG. 6, the RNC 710 determines the main cell, but the subject determining the main cell may be a terminal.

Hereinafter, an operation of exchanging control messages between the UE and the RNC when the UE determines the primary cell will be described.

Referring to FIG. 7, in step 815, the RNC 805 determines configuration information of an E-DCH active set, and transmits configuration information of the determined E-DCH active set to the terminal 805. In step 820, the terminal 805 receives configuration information of the E-DCH active set, and transmits a response to the RNC 810.

In step 825, the UE 805 determines a cell that best meets a predetermined condition among the cells belonging to the E-DCH active set as the main cell, and notifies the cells belonging to the E-DCH active set. The predetermined condition may be a cell or the like with the best radio channel condition. As a method of notifying the primary cell information to the cells belonging to the E-DCH active set, an in-band method of inserting and transmitting the primary cell information in the E-DPDCH may be used. Since the operation is irrelevant, detailed description thereof will be omitted.

In step 830, the UE 805 configures a primary RG-RLS to perform 1-layer combining, and in step 835, 1-layer for cells having the same secondary RG-RLS ID among cells not included in the primary RG-RLS. Perform the combining.

8 is a diagram illustrating an operation of a terminal for determining cells to which 1-layer combining is applied according to a first embodiment of the present invention.

Referring to FIG. 8, in step 905, after receiving the E-DCH active set configuration information, the UE configures the E-DCH active set and recognizes a main cell.

In step 910, the UE checks whether the main RG-RLS configuration information for the primary cell exists in the E-DCH active set configuration information. Here, the main RG-RLS configuration information includes channel information of the E-RGCH and the main RG-RLS ID. If there is no main RG-RLS configuration information for the primary cell as a result of the check, it means that the E-RGCH is not transmitted in the primary cell in step 930, and thus proceeds to step 935 without receiving the E-RGCH from the serving cell. do..

If there is the main RG-RLS configuration information for the main cell as a result of the check, step 915 is performed. In step 915, the terminal inputs a primary RG-RLS ID of the primary cell into a variable 'current_serving_RG_RLS_id'. In step 920, the terminal includes a primary RG-RLS ID of cells belonging to an E-DCH active set. It checks whether there is a cell equal to the value stored in current_serving_RG_RLS_id ', and configures the main RG-RLS with cells and main cells meeting the above conditions.

In step 925, the UE performs one-layer combining on E-RGCHs of cells included in the main RG-RLS. In step 935, the UE configures the secondary RG-RLS by collecting cells having the same secondary RG-RLS ID among cells not included in the primary RG-RLS. In this case, a plurality of secondary RG-RLS may be configured. In step 940, the UE performs 1-layer combining on the E-RGCHs of cells belonging to each secondary RG-RLS.

Hereinafter, in the second embodiment of the present invention, only one 'RG-RLS ID' is allocated to cells, and the UE performs 1-layer combining using scheduling mode information of cells for cells belonging to the secondary RG-RLS. Suggest ways to do it. That is, when the RG control mode is common, 1 layer combining with E-RGCH of another cell is not performed.

9 is a view schematically showing a second embodiment of the present invention. Here, similarly to the situation assumed in FIG. 4, the RNC configures E-RGCHs of respective cells as follows.

When the E-RGCH of the cell 1 1015 belongs to the primary RG-RLS, the layer 1 combines with the E-RGCH of the cell 2, and does not belong to the main RG-RLS (Serving Rate Grant-Radio Link Set) 1045. RG control mode is common. If the E-RGCH of the cell 2 (1020) belongs to the main RG-RLS (1045), it combines with the E-RGCH of the cell 1 (1015) one layer. If it does not belong to the main RG-RLS 1045, the RG control mode is common.

If the E-RGCH of cell 3 (1025) belongs to the primary RG-RLS (1045), the layer 1 combines with the E-RGCH of cell 4 (1030), and if it does not belong to the main RG-RLS (1045), the RG control mode is It is dedicate and combines E-RGCH with cell 4 in one layer. E-RGCH in cell 4 (1030) is one layer combine with E-RGCH (1050) in cell 3 (1025) if it belongs to primary RG-RLS (1045), and RG if it belongs to primary RG-RLS (1045). The control mode is dedicate and combines E-RGCH of cell 3 with 1 layer.                     

The E-RGCH of cell 5 (1035) does not combine 1 layer when belonging to the main RG-RLS (1045), and the RG control mode is common when it does not belong to the main RG-RLS (1050).

When the terminal 1040 receives the RG-RLS configuration information for each cell and checks the main cell, the terminal 1040 recognizes the cells and the main cell having the same RG-RLS ID as the main cell as the main RG-RLS 1045. Thereafter, layer 1 combining is performed on E-RGCHs of cells included in the main RG-RLS 1045.

Referring to FIG. 9, if the main cell is cell 1 1015, cell 2 1020 having the same RG-RLS ID as S1 which is the RG-RLS ID of the main cell 1015 and cell 1 1015 which is the main cell are shown. Recognized as the primary RG-RLS 1045, one-layer combining is performed on the E-RGCH of the cell 1 and the E-RGCH of the cell 2.

The UE 104 configures the secondary RG-RLS 1050 by collecting cells having the same RG-RLS ID among cells not included in the primary RG-RLS 1045 and having an RG control mode dedicate. Referring to the example of FIG. 9, cells not included in the main RG-RLS are cell 3 (1025), cell 4 (1030), and cell 5 (1035). Among these, cells with dedicated RG control mode are cell 3 (1025). And cell 4 1030, and the RG RLS IDs of the cell 3 1025 and the cell 4 1030 are the same as S2, so the two cells are recognized as one sub-RG-RLS 1050.

The terminal 105 performs one-layer combining on E-RGCHs of cells belonging to the same secondary RG-RLS 1050.

10 is a diagram illustrating a control message exchange operation between a terminal and an RNC according to a second embodiment of the present invention.                     

Referring to FIG. 10, the terminal 1105 periodically reports a measurement result of a channel condition of a neighbor cell to the RNC 1110 when a specific condition is satisfied. The RNC 1110 sets an E-DCH active set based on the measurement result.

For example, the E-DCH active set may consist of cells whose channel condition is better than a certain criterion. The cells belonging to the E-DCH active set process the E-DPDCH transmitted by the terminal 1105 and transmit an E-RGCH signal to the terminal 1105.

In step 1115, the RNC 1110 determines cells to be included in the E-DCH active set, determines configuration information of the E-DCH active set, and transmits configuration information of the E-DCH active set to the UE. The E-DCH active set configuration information includes identifiers of cells included in the E-DCH active set, RG-RLS ID, primary RG-RLS configuration information, and secondary RG-RLS configuration information for each cell. The primary RG-RLS configuration information includes channel information of the E-RGCH, and the secondary RG-RLS configuration information includes channel information of the E-RGCH and the RG control mode. The RG-RLS ID is an integer assigned to each cell and is used for identifying cells to perform 1-layer combining.

When determining the RG-RLS ID of the cell, the RNC determines that the following conditions are met.

The RG-RLS ID for any 'cell x' should be the same as the RG-RLS ID of the cells to perform 1-layer combining for the E-RGCH when the cell x is the main cell. In addition, the RNC 1110 determines the RG control mode for each cell in consideration of the number of terminals for each cell. For example, if a plurality of terminals have already assigned dedicate E-RGCHs in an arbitrary cell, it is preferable to assign common E-RGCHs to subsequent terminals. On the other hand, if a dedicate E-RGCH is allocated to only a small number of terminals in an arbitrary cell, the dedicate E-RGCH may be allocated to other terminals.

When the UE 1105 receives the E-DCH active set configuration information in step 1120, it configures an E-DCH active set according to the information, and transmits a response message to the RNC 1110. In step 1125, the RNC 1110 transmits an identifier of a cell that will serve as a primary cell in the E-DCH active set to the UE. The identifier of the primary cell may be included in the E-DCH active set configuration information in step 1115 without going through a separate step 1125.

In step 1130, the terminal receives the identifier of the primary cell, and transmits a response message to the RNC 1110. In step 1135, the UE 1105 configures a primary RG-RLS with cells having the same RG-RLS ID as the 'RG-RLS ID of the primary cell' and the primary cell, and then is transmitted from the cells of the primary RG-RLS. Layer 1 combining is performed on the E-RGCHs.

In step 1140, the UE 1105 selects cells to perform 1-layer combining by checking RG-RLS IDs of cells not included in the main RG-RLS. That is, among the cells not included in the main RG-RLS, one layer combining is performed on cells in which the RG control mode is dedicate and the same RG-RLS ID.

In FIG. 10, the RNC determines the main cell, but the subject determining the main cell may be a terminal.

Hereinafter, referring to FIG. 11, when a terminal is a subject that determines a primary cell, a control message operation between the terminal and the RNC will be described.

In step 1215, the RNC 1210 determines configuration information of the E-DCH active set, transmits configuration information of the E-DCH active set to the terminal 1205, and in step 1220, the terminal 1205 determines the E-DCH active set. A response message indicating that the DCH active set configuration information has been received is transmitted to the RNC 1210.

In step 1225, the UE 1205 determines, as a main cell, a cell that best meets a predetermined condition among the cells belonging to the E-DCH active set, and notifies the cells belonging to the E-DCH active set. The predetermined condition may be a cell or the like in which the wireless channel situation is best. As a method of notifying the primary cell information to the cells belonging to the E-DCH active set, an in-band method of inserting and transmitting the information into the E-DPDCH may be used and is an operation irrelevant to the gist of the present invention. , Detailed description is omitted.

In step 1230, the UE 1205 configures the primary RG-RLS to perform 1-layer combining, and in step 1235, the RG control mode is dedicated with the same RG-RLS ID among cells not included in the primary RG-RLS. 1 layer combining is performed on the cells.

12 illustrates an operation of determining, by the terminal, cells to which to apply 1-layer combining.

12, in step 1305, the UE receives the E-DCH active set configuration information, configures the E-DCH active set, and recognizes a main cell.

In step 1310, the UE checks whether the primary RG-RLS configuration information for the primary cell exists in the E-DCH active set configuration information. If the main RG-RLS configuration information does not exist in the main cell as a result of the check, it means that the E-RGCH is not transmitted in the main cell. In step 1330, the UE does not receive the E-RGCH from the serving cell. Proceed to step.

If there is the primary RG-RLS configuration information for the primary cell as a result of the check, in step 1315, the terminal inputs the RG-RLS ID of the primary cell to a variable 'current_serving_RG_RLS_id'. In step 1320, the UE checks whether there is a cell whose RG-RLS ID is equal to the value stored in 'current_serving_RG_RLS_id' among cells belonging to the E-DCH active set, and configures the main RG-RLS as cells and main cells meeting the above conditions. . In step 1325, the UE performs 1-layer combining on the E-RGCHs of cells included in the primary RG-RLS.

In step 1335, the UE is not included in the primary RG-RLS, and among the cells having the RG control mode dedicate, cells having the same RG-RLS ID are collected to form the secondary RG-RLS. In this case, a plurality of secondary RG-RLS may be configured. In step 1340, the UE performs 1-layer combining on the E-RGCHs of cells belonging to each secondary RG-RLS.

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 those equivalent to the scope of the claims.

 In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

The present invention has the effect of improving the reliability of the E-RGCH signal by allowing the UE to correctly perform 1-layer combining the E-RGCHs of different cells in the soft handover region.

Claims (13)

In the mobile communication system consisting of a base station consisting of a plurality of cells, and a radio network controller for managing radio resources of the base stations and cells, transmitting packet data through an uplink channel (E-DCH), soft hand A method for performing layer 1 combining when the radio network controller determines a primary cell in an over area, Setting an 'E-DCH active set' which is a set of cells processing the E-DCH according to a channel condition of a cell; Configuration information when the primary RG-RLS (Serving Relative Grant-Radio Link Set) is configured for the cells among the cells included in the E-DCH active set and configuration information when the secondary RG-RLS is configured Method comprising the step of transmitting to, characterized in that The method as claimed in claim 1, wherein the configuration information of the primary RG-RLS and the secondary RG-RLS consists of an RG-RLS identifier. The method of claim 1, Determining configuration information of the E-DCH active set, If any cells included in the same node ratio are included in the primary RG-RLS, assign a 'primary RG-RLS identifier' that is the same as the primary RG-RLS ID of the primary cell, If the cells are not included in the primary RG-RLS, a method of assigning different or identical secondary RG-RLS identifiers, The method of claim 3, wherein Assigning different primary RG-RLS identifiers if desired to individually schedule some of the cells belonging to the same node ratio. The method of claim 1, wherein the configuration information of the E-DCH active set is And the identifiers of the cells included in the E-DCH active set. The method according to claim 1, wherein the primary RG-RLS configuration information includes channel information of the E-RGCH of the primary cell and the primary RG-RLS ID, and the secondary RG-RLS configuration information includes the E- of the secondary cell. And channel information of the RGCH, secondary RG-RLS ID, and relative tolerance control mode information. In the mobile communication system consisting of a base station consisting of a plurality of cells, and a radio network controller for managing radio resources of the base stations and cells, transmitting packet data through an uplink channel (E-DCH), soft hand A method for performing layer 1 combining when a terminal communicating with the radio network controller in an over area determines a primary cell, Receiving 'E-DCH active set' configuration information, which is a set of cells processing an E-DCH, from the radio network controller; Among the cells belonging to the E-DCH active set, an EDCH-Relative Grant Channel (E-RGCH) coming from a predetermined primary cell and a 'primary RG-RLS identifier' equal to the 'primary RG-RLS identifier' of the determined primary cell Performing 'first layer combining' on the E-RGCH coming from cells having E-RGCH transmitted from cells having the same 'secondary RG-RLS identifier' after configuring 'secondary RG-RLS' from cells having the same 'secondary RG-RLS identifier' among cells not included in the primary RG-RLS. And performing a 'first layer combining'. The method of claim 7, wherein the E-DCH active set configuration information, A cell to perform layer 1 combining with an identifier of cells included in the E-DCH active set, the RG-RLS configuration information, and an E-RGCH transmitted from a subcell among cells not included in the RG-RLS. And configuration information of the E-DCH active set including the configuration information of 'sub RG-RLS', which is a set of data sets. The method according to claim 8, wherein the primary RG-RLS configuration information includes channel information of the E-RGCH of the primary cell and the primary RG-RLS identifier, and the secondary RG-RLS configuration information includes the E- of the secondary cell. And channel information of the RGCH, secondary RG-RLS identifier and relative tolerance control mode information. In the mobile communication system consisting of a base station consisting of a plurality of cells, and a radio network controller for managing radio resources of the base stations and cells, transmitting packet data through an uplink channel (E-DCH), soft hand A method for performing layer 1 combining when a terminal communicating with the radio network controller in an over area determines a primary cell, Receiving 'E-DCH active set' configuration information, which is a set of cells processing an E-DCH, from the radio network controller; Among the cells belonging to the E-DCH active set, an EDCH-Relative Grant Channel (E-RGCH) coming from a predetermined primary cell and a 'primary RG-RLS identifier' equal to the 'primary RG-RLS identifier' of the determined primary cell Performing 'first layer combining' on the E-RGCH coming from cells having E-RGCH transmitted in cells not included in the primary RG-RLS and cells having the same 'primary RG-RLS identifier' among cells whose relative tolerance control mode of cells not included in the primary RG-RLS is 'dedicated' And performing a 'first layer combining' with respect to the method. The method of claim 10, wherein the E-DCH active set configuration information, Identifiers of cells included in the E-DCH active set, the RG-RLS configuration information, and cells to perform 1-layer combining with E-RGCH transmitted from a subcell among cells not included in the RG-RLS. And configuration information of an E-DCH active set including configuration information of a sub-RG-RLS configuration. 12. The apparatus of claim 11, wherein the primary RG-RLS configuration information includes channel information of the E-RGCH of the primary cell and the primary RG-RLS identifier, and the secondary RG-RLS configuration information includes the E- of the secondary cell. The channel information of the RGCH and the relative tolerance control mode information. The method of claim 12, wherein the relative tolerance control mode information, A method of controlling a transmission rate of a plurality of terminals, or a 'public absolute allowance' for adjusting the transmission rate of one terminal.

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