CN101345970B

CN101345970B - Method for measuring neighbor community interference of multi-carrier wave reinforced ascending access system

Info

Publication number: CN101345970B
Application number: CN2007101305026A
Authority: CN
Inventors: 刘虎; 殷玮玮; 费佩燕; 孙慧霞; 夏中英; 李轶; 张银成; 陈慧; 肖炼斌
Original assignee: ZTE Corp
Current assignee: ZTE Corp
Priority date: 2007-07-09
Filing date: 2007-07-09
Publication date: 2012-06-06
Anticipated expiration: 2027-07-09
Also published as: CN101345970A

Abstract

A multicarrier enlargement upstream access system neighbour district interference measuring method, comprises: step s202: wireless network controller allocating a supportable amount of carrierwaves for NodeB and subscriber equipment and allocating dominant carrierwave frequency point marks, subsidiary carrierwave frequency point marks of service district of subscriber equipment required for measuring and reporting and neighbour district of the service district and path-loss correction parameters of the service district and neighbour district for subscriber equipment; step s204, wireless network controller sending dominant carrierwave frequency point marks, subsidiary carrierwave frequency point marks and path-loss correction parameters of the service district and neighbour district to subscriber equipment; step s206, subscriber equipment measuring dominant carrierwave path-loss of service district based on dominant carrierwave frequency point marks, subsidiary carrierwave frequency point marks and path-loss correction parameters, and calculating subsidiary carrierwave path-loss of service district, and measuring dominant carrierwave path-loss of neighbour district and calculating subsidiary carrierwave path-loss of neighbour district.

Description

Method for measuring adjacent cell interference of multi-carrier enhanced uplink access system

Technical Field

The present invention relates to the field of communications, and in particular, to a method for measuring neighboring cell interference in a multi-carrier enhanced uplink access system.

Background

An enhanced uplink Access system is generally called a High Speed Uplink Packet Access (HSUPA) system, and aims to improve uplink efficiency through advanced technology, thereby effectively supporting web browsing, video, multimedia information, and other IP-based services.

The third generation partnership project (3GPP) has completed standardization of time division synchronous code division multiple access (TD-SCDMA) enhanced uplink access system. The system is suitable for a single carrier TD-SCDMA system. A new transport channel, namely an enhanced uplink dedicated transport channel (E-DCH), is added in an Enhanced Uplink (EUL), enhanced uplink data is carried on the transport channel, and the Transmission Time Interval (TTI) of the E-DCH is 5 ms. The packet mapped onto the E-DCH transport channel is called an enhanced medium access control protocol data unit (MAC-E PDU).

The physical channels associated with the E-DCH are as follows:

enhanced uplink control channel (E-UCCH): the channel is a physical layer control channel, which is carried in a physical layer indication field of the E-PUCH, wherein the control information includes: an enhanced uplink transport format indicator (E-TFCI) for indicating a current transport block length; and hybrid automatic repeat request (HARQ) information including a process ID and retransmission number information;

an E-AGCH channel (E-DCH absolute grant channel), which is a control channel and is used for transmitting grant information for a Node B (base station);

an E-PUCH (E-DCH uplink physical channel, also called enhanced uplink physical channel), which is a traffic channel and is used for a UE (User Equipment, User terminal, also called User Equipment) to carry E-DCH transport channel data, and in addition, information related to auxiliary scheduling is also transmitted on the channel;

E-RUCCH (E-DCH random access uplink control channel, i.e., enhanced uplink random access uplink control channel), which is a physical layer control channel for UE to transmit auxiliary scheduling related information without grant, the E-RUCCH using random access physical channel resources;

an E-HICH (E-DCH hybrid automatic repeat request indicator channel), which is a physical layer control channel for enabling the Node B to carry HARQ (hybrid automatic repeat request) indication information.

The enhanced uplink access service can be divided into a scheduling service and a non-scheduling service according to different scheduling modes. Wherein, the resource of the non-scheduling service is allocated to the UE by RNC (radio network controller), and the allocation mode is the same as the existing dedicated channel allocation mode; in the scheduling service, the serving rnc (srnc) allocates an enhanced uplink resource pool to the Node B, and the Node B allocates resources to a single UE. In the scheduling service, the UE needs to report some information to assist the scheduling of the Node B, where the information is called scheduling information si (scheduling information), and the information includes UE buffer information, power headroom, path loss (path loss, hereinafter, abbreviated as path loss) measurement information of the serving cell and the neighboring cell, and the like.

Fig. 1 is a signaling flow diagram of the main traffic processing performed by the entities involved in scheduling traffic. In the figure, RNC 1 allocates a scheduling service resource pool (102) to NodeB 2, is responsible for admission control (106), and configures a scheduling service bearer parameter (112) for the UE according to the allocation (110) of the NodeB to a scheduling service shared control channel; the NodeB 2 configures a resource pool to return a response (104) according to the instruction of the RNC, allocates resources (116) for the UE according to the scheduling request of the UE, and performs HARQ confirmation (120); UE 3 transmits a scheduling request when there is data transmission in the uplink to trigger transmission of scheduling information (114), performs transmission of data according to the grant of the NodeB (116 and 118), and confirms reception of information (120).

The scheduling request information includes buffer information, path loss information and power headroom information, wherein the path loss information is a reference amount of interference of NodeB control on the neighboring cell, and a path loss ratio (SNPL) between the neighboring cell and the serving cell can be obtained through the path loss information, and the expression is:

formula (1):

or formula (2):

wherein L is the path loss measured by the UE, L_servFor serving cell path loss, L_nFor the adjacent cell path loss, the UE needs to report the information, and the Node B schedules the UE according to the information, which determines whether the UE is scheduled and allocates authorized resources to the UE (the authorized resources include authorization for power, code channel, and time slot).

To further improve the throughput of the system, the single carrier enhanced uplink system in the related art introduces a multi-carrier characteristic, and theoretically, N carriers will have N times the throughput of the single carrier system. When introducing the multi-carrier characteristic, there will be a plurality of architectures considered, one possible architecture is the multi-carrier bundling mechanism, i.e. the UE can simultaneously transmit E-DCH data on a plurality of carriers in one TTI, and the data blocks transmitted by each carrier are independent. This architecture is adopted when HSDPA (high speed downlink packet access) introduces multi-carrier characteristics, which has the advantage that the peak rate of a single UE can be increased.

In the above-mentioned multi-carrier bundling mechanism, the interference situation of each carrier reported by the UE will determine the number of carriers allocated by the NodeB to the UE in one TTI and the authorized resources on each carrier. Since the primary and secondary carriers of adjacent cells are different, for example, the primary carrier of the serving cell may be the secondary carrier of the adjacent cell, and there may be no common downlink channel on the secondary carrier, in this case, the UE may not be able to directly measure the interference of the adjacent cell on the carrier, and an effective scheme for how the UE measures and reports the information of each carrier has not been proposed so far.

Disclosure of Invention

The present invention has been made in view of the above problems, and it is therefore a primary object of the present invention to provide a scheme for measuring neighbor cell interference in a multi-carrier enhanced uplink access system.

According to the embodiment of the invention, a method for measuring the interference of a neighboring cell of a multi-carrier enhanced uplink access system is provided.

The method comprises the following steps: step S202, a wireless network controller configures the carrier of the quantity for NodeB and user equipment according to the quantity of the carrier which can be supported by the user equipment and reported by the user equipment, and configures the main carrier frequency point identifier, the auxiliary carrier frequency point identifier and the path loss correction parameters of the service cell and the adjacent cell of the service cell where the user equipment is located and the adjacent cell of the service cell which need to be measured and reported for the user equipment;

step S204, the wireless network controller issues the main carrier frequency point identification, the auxiliary carrier frequency point identification and the path loss correction parameter of the service cell and the adjacent cell to the user equipment; and

step S206, according to the transmitted main carrier frequency point identification, the auxiliary carrier frequency point identification and the path loss correction parameter of the serving cell and the adjacent cell, the user equipment measures the main carrier path loss of the serving cell, calculates the auxiliary carrier path loss of the serving cell, measures the main carrier path loss of the adjacent cell and calculates the auxiliary carrier path loss of the adjacent cell.

Before step S206, the method may further include: establishing a propagation model, and calculating the path loss of the auxiliary carrier of the service cell according to the relationship between the frequency difference and the path loss difference between the main carrier of the service cell and the auxiliary carrier of the service cell in the propagation model; and calculating the path loss of the auxiliary carrier wave of the adjacent cell according to the relationship between the frequency difference and the path loss difference between the main carrier wave of the adjacent cell and the auxiliary carrier wave of the adjacent cell in the propagation model.

In step S206, if the co-frequency carrier of the neighboring cell corresponding to the primary carrier and/or the secondary carrier of the serving cell does not exist, the ue calculates the path loss of the co-frequency carrier of the neighboring cell to be infinite.

In step S206, the path loss of the secondary carrier of the serving cell and the path loss of the secondary carrier of the neighboring cell are calculated by the following formulas:

wherein,

as the path loss of the secondary carrier of the serving cell,

as the primary carrier path loss of the serving cell,is the path loss of the auxiliary carrier of the adjacent cell,

path loss of main carrier of adjacent cell, alpha_servCorrection value of path loss of secondary carrier for serving cell, alpha_neibAnd the path loss correction value of the auxiliary carrier of the adjacent cell is obtained.

In this case, based on the propagation model, the path losses of the secondary carriers of the serving cell and the neighboring cell are calculated based on the measured path losses of the primary carriers of the serving cell and the neighboring cell, respectively, and the difference between the path loss of the primary carrier of the serving cell and the path loss of the secondary carrier of the serving cell is defined as α_servAnd taking the difference between the path loss of the main carrier of the adjacent cell and the path loss of the auxiliary carrier of the adjacent cell as alpha_neib。

Further, the propagation model may be a cost-231 model, and parameters of the propagation model may be obtained in step S204 or determined by the user equipment.

The method may further comprise: and calculating the path loss ratio of the adjacent cell and the serving cell according to the measurement result and the calculation result in the step S206, and reporting the ratio.

By the technical scheme of the invention, the path loss of the main carrier and the path loss of the auxiliary carrier of the adjacent cell can be effectively measured, and the co-frequency interference between the service cell and the adjacent cell is determined by calculation and measurement as less as possible.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

fig. 1 is a signaling flow diagram of main processing performed by a network function entity in a single carrier enhanced uplink access system according to the related art;

fig. 2 is a schematic flowchart of a method for measuring neighbor cell interference in a multi-carrier enhanced uplink access system according to an embodiment of the present invention;

fig. 3 is a flowchart of an example of a process of a method for measuring neighbor cell interference in a multi-carrier enhanced uplink access system according to an embodiment of the present invention; and

fig. 4 is a signaling flowchart of a processing example of a method for measuring neighbor cell interference in a multi-carrier enhanced uplink access system according to an embodiment of the present invention.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

In the multi-carrier HSUPA according to the related art, the UE must report the path loss of the primary carrier or the secondary carrier of the neighboring cell regardless of whether the SNPL is reported independently by each carrier or the SNPL value of each carrier is reported on one carrier.

In the current multi-carrier protocol, the primary carriers between adjacent cells may be different, and there may be no downlink common channel on the secondary carrier, so the following two situations will occur:

(1) the UE supports multiple carriers, but the UE may not be able to directly measure the path loss of the secondary carrier of the adjacent cell, because the secondary carrier in the current multi-carrier protocol may not have a downlink common channel required by the UE to measure the path loss; (2) the UE supports multiple carriers, but the UE cannot know the carrier configuration condition of the neighboring cell, that is, cannot know whether the carrier of the serving cell where the UE is located is the same frequency as the carrier of the neighboring cell.

In this embodiment, a method for measuring interference of a neighboring cell in a multi-carrier enhanced uplink access system is provided, which can effectively solve the problem in the related art that a UE cannot know the path loss of a primary carrier and/or a secondary carrier of a neighboring cell.

As shown in fig. 2, the method for measuring interference of neighboring cells in a multi-carrier enhanced uplink access system according to this embodiment includes:

step S202, a wireless network controller configures the carrier of the quantity for NodeB and user equipment according to the quantity of the carrier which can be supported by the user equipment and reported by the user equipment, and configures the main carrier frequency point identifier, the auxiliary carrier frequency point identifier and the path loss correction parameters of the service cell and the adjacent cell of the service cell where the user equipment is located and the adjacent cell of the service cell which need to be measured and reported for the user equipment;

In step S202, when a radio resource control link (RRC) is established or a Radio Link Control (RLC) layer is reconfigured, the radio network controller issues the main carrier frequency point identifier, the auxiliary carrier frequency point identifier, and the path loss correction parameter of the serving cell and the neighboring cell to the user equipment. Preferably, the radio network controller may feed back carrier frequency point identifications of the serving cell and the neighbor cells to the user equipment in the form of table 1.

TABLE 1

Further, before step S206, the method may further include: establishing a propagation model, and calculating the path loss of the auxiliary carrier of the service cell according to the relationship between the frequency difference and the path loss difference between the main carrier of the service cell and the auxiliary carrier of the service cell in the propagation model; and calculating the path loss of the auxiliary carrier wave of the adjacent cell according to the relationship between the frequency difference and the path loss difference between the main carrier wave of the adjacent cell and the auxiliary carrier wave of the adjacent cell in the propagation model.

In step S206, if the co-frequency carrier of the neighboring cell corresponding to the primary carrier and/or the secondary carrier of the serving cell does not exist, the ue calculates the path loss of the carrier in the neighboring cell to be infinite.

Preferably, in step S206, the secondary carrier path loss of the serving cell and the secondary carrier path loss of the neighbor cell may be calculated by the following formulas:

formula (3):

formula (4):

wherein,

as the path loss of the secondary carrier of the serving cell,

as the primary carrier path loss of the serving cell,

is the path loss of the auxiliary carrier of the adjacent cell,

In this case, based on the propagation model, the path losses of the secondary carriers of the serving cell and the neighboring cell are calculated based on the measured path losses of the primary carriers of the serving cell and the neighboring cell, respectively, and the difference between the path loss of the primary carrier of the serving cell and the path loss of the secondary carrier of the serving cell is defined as α_servAnd taking the difference between the path loss of the main carrier of the adjacent cell and the path loss of the auxiliary carrier of the adjacent cell as alpha_neib. In the same propagation model, the path loss corresponding to different frequencies is different.

As shown in table 1, for example, the UE supports 3 carriers, the system has 4 neighboring cells, and the RNC needs to send a neighboring cell carrier configuration table (table 1) to the UE, where the numbers with lower lines are the primary carriers of each cell, that is, the primary carriers of the serving cell, the neighboring cell 1, the neighboring cell 2, the neighboring cell 3, and the neighboring cell 4 where the UE is located are carriers No. 2, 3, 4, 5, and 1, respectively. The carriers used by the serving cell are

numbers

2, 3, and 4, and for the serving cell, the UE needs to measure the path loss of the number 2 primary carrier according to table 1, and calculate the path loss on the corresponding number 3 and number 4 secondary carriers according to formula (3); for the adjacent cell 1, the UE needs to measure the path loss of the number 3 primary carrier according to table 1, and does not need to calculate the path loss on other carriers of the adjacent cell; for the adjacent cell 2, the UE needs to measure the path loss of the number 4 main carrier according to table 1, and calculate the path loss on the number 2 carrier according to formula (4); for the adjacent cell 3, the UE needs to measure the path loss of the number 5 main carrier according to table 1, and calculate the path loss of the number 2 and number 3 carriers according to formula (4); for the neighboring cell 4, the UE needs to measure the path loss of the number 1 primary carrier according to table 1, and calculate the path loss on the corresponding number 4 carrier according to formula (4). That is, the carriers to be measured and calculated in the neighboring cell are determined by this process.

Wherein α can be calculated by the following process_servAnd alpha_neib：

Further, preferably, in step S208, the SNPL may be calculated by formula (1) or formula (2), and when there is no co-channel interference between the serving cell and the neighbor cell, the path loss of the primary carrier and the secondary carrier in formula (1) and formula (2) is infinite.

For example, a cost-231 model can be used for simulation, and the path loss correction values of the serving cell and the neighboring cells are calculated by the following formula:

formula (5): alpha is alpha_serv＝βlogf_{a_serv}-βlogf_{m_serv}，

Formula (6): alpha is alpha_neib＝βlogf_{a_neib}-βlogf_{m_neib}。

Where β is a propagation model coefficient, β may be taken to be 33.9 in the cost-231 model, and f is a carrier frequency. Therein, various parameters of the propagation model may be obtained in step S204 or determined by the user equipment.

In addition, the method may further include: and calculating the path loss ratio of the adjacent cell and the serving cell according to the measurement result and the calculation result in the step S206, and reporting the ratio. Preferably, the ratio may be calculated by formula (1) or formula (2).

An example of the processing of this method will be described below.

Referring to fig. 1 and 4, the method according to the present embodiment may include the following processes:

corresponding to 106 in fig. 1, the UE reports its supportable carrier identifier (for example, a number corresponding to a carrier) in a radio resource control link establishment linking request or a radio link control layer reestablishment request;

corresponding to 108 in fig. 1, the radio network controller configures, for the NodeB, the multi-carrier identities supported by the UE, and the carriers (frequency points) of the neighbor cells and serving cells that need to be measured;

corresponding to 404 in fig. 4, the radio network controller configures the neighboring cell carriers (frequency points) to be measured and reported for the UE;

corresponding to 406 in fig. 4, the UE measures the primary carrier path loss and calculates the secondary carrier path loss;

corresponding to 114 in fig. 1, the UE transmits SNPL information through a scheduling request;

then, the processing according to the embodiment of the present invention is performed, that is, the carrier path loss of the neighboring cell and the serving cell measured by the UE is as shown in fig. 3, which specifically includes the following steps:

302, the UE reads carrier information when a radio resource control link is established or a radio link control layer is reconfigured;

304, the UE measures the path loss of the main carrier of the service cell, and calculates the path loss of the auxiliary carrier of the service cell according to a formula (3) according to the carrier information when the radio resource control link is established or the radio link control layer is reconfigured;

306, the UE determines whether to measure the path loss of a certain frequency point of the adjacent cell according to the carrier information when the radio resource control link is established or re-established;

307, if the neighboring cell does not have the frequency point, the path loss of the frequency point in the neighboring cell is infinite;

310, if necessary, measuring the main carrier of the adjacent cell, and calculating the path loss of the auxiliary carrier to be measured of the adjacent cell according to the carrier (frequency point) configuration and the formula (4);

the UE judges whether the frequency points of the adjacent cells need to be measured (312);

if not, selecting the frequency point of the next adjacent cell for measurement (308), and repeating 306, 310 and 312;

314, if the measurement is finished, calculating SNPL and reporting to NodeB through SI message.

Fig. 4 shows a signalling flow diagram of a processing example of a method according to an embodiment of the invention. As shown in fig. 4, RNC 1 reports the maximum uplink transmission power when a radio resource control link is established or a radio link control layer is reconfigured, where the reported content may include a carrier list of a serving cell (this cell) and an adjacent cell, identifiers of a primary carrier and an auxiliary carrier, and an auxiliary carrier path loss correction parameter (402); sending scheduling service control parameters to the UE 3, wherein the parameters comprise carrier lists of a serving cell and an adjacent cell, main carrier and auxiliary carrier identifications and auxiliary carrier path loss correction parameters (404); then, UE 3 measures and calculates the path loss (406), UE 3 sends a scheduling request, which includes the power headroom of each carrier in the serving cell where it is located; after authorization by NodeB 2, UE 3 data is sent to NodeB 2(412), and an acknowledgement indication from NodeB 2 is received (414).

In summary, by means of the technical scheme of the present invention, the main carrier path loss and the auxiliary carrier path loss of the neighboring cell can be effectively measured, the co-channel interference existing between the serving cell and the neighboring cell is determined by calculation and measurement as less as possible, and the blank in the related art is filled.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A method for measuring interference of a neighboring cell of a multi-carrier enhanced uplink access system is characterized by comprising the following steps:

step S202, a radio network controller configures carriers of the number for NodeB and user equipment according to the number of the carriers which can be supported by the user equipment and is reported by the user equipment, and configures a serving cell where the user equipment is located and a main carrier frequency point identifier and a secondary carrier frequency point identifier of a neighboring cell of the serving cell, which need to be measured and reported, and path loss correction parameters of the serving cell and the neighboring cell for the user equipment;

step S204, the wireless network controller sends the main carrier frequency point identification, the auxiliary carrier frequency point identification and the path loss correction parameter of the service cell and the adjacent cell to the user equipment; and

step S206, according to the transmitted main carrier frequency point identifier, auxiliary carrier frequency point identifier and path loss correction parameter of the serving cell and the adjacent cell, the UE measures the main carrier path loss of the serving cell, calculates the auxiliary carrier path loss of the serving cell, measures the main carrier path loss of the adjacent cell, and calculates the auxiliary carrier path loss of the adjacent cell;

wherein the step S206 includes: establishing a propagation model, and calculating the path loss of the auxiliary carrier of the service cell according to the relationship between the frequency difference and the path loss difference between the main carrier of the service cell and the auxiliary carrier of the service cell in the propagation model; and calculating the path loss of the auxiliary carrier wave of the adjacent cell according to the relationship between the frequency difference and the path loss difference between the main carrier wave of the adjacent cell and the auxiliary carrier wave of the adjacent cell in the propagation model.

2. The method according to claim 1, wherein in step S206, when there is no co-channel carrier of the neighboring cell corresponding to the primary carrier and/or the secondary carrier of the serving cell, the ue calculates the path loss of the co-channel carrier of the neighboring cell to infinity.

3. The method of claim 1, wherein in step S206, the path loss of the secondary carrier of the serving cell and the path loss of the secondary carrier of the neighboring cell are calculated according to the following formulas:

wherein,

serv is the secondary carrier path loss of the serving cell,

for the primary carrier path loss of the serving cell,

is the path loss of the auxiliary carrier of the adjacent cell,

is the path loss of the main carrier of the adjacent cell, alpha_servIs a secondary carrier path loss correction value, alpha, for the serving cell_neibAnd the path loss correction value is the auxiliary carrier path loss correction value of the adjacent cell.

4. The method of claim 1, wherein the propagation model is a cost-231 model.

5. The method of claim 1, wherein parameters of the propagation model are obtained in step S204 or determined by the ue.

6. The method of claim 1, further comprising: and calculating the path loss ratio of the neighboring cell and the serving cell according to the measurement result and the calculation result in the step S206, and reporting the ratio.