KR101136485B1 - System and method for uplink transmittion - Google Patents

Abstract

The present invention relates to an uplink transmission method.

The uplink transmission method according to the present invention relates to a method for uplink transmission by mobile stations using beamforming and access control in a cellular mobile communication system. The method includes: (a) an average channel between a mobile station and a plurality of candidate base stations on a predetermined time basis; Measuring a fading channel, and (b) using the measured channel information, selecting a beamforming vector to be used for beamforming in the mobile station and an access base station to be connected to the mobile station among a plurality of candidate base stations.

According to the present invention, it is possible to improve the performance of a cellular mobile communication system by using an efficient method of forming a beam and simultaneously controlling the connection.

Beamforming, access control, utility maximization, network optimization

Description

Uplink transmission method and its system {SYSTEM AND METHOD FOR UPLINK TRANSMITTION}

The present invention relates to an uplink transmission method.

In current cellular mobile communication systems, mobile stations take some action regardless of information about network conditions. For example, a decision on which base station the terminal will access is mostly made regardless of network conditions. As such, the terminals access the base station where the strongest received signal is detected. According to this access method, since a large number of users (terminals) and traffic can be concentrated in one base station, some base stations in a complex host spot have a heavy load. Accordingly, a load imbalance phenomenon with a relatively low load may be caused between other base stations around. This situation means that the user needs to develop a more efficient access method in selecting a base station. The technique of adjusting the base station to be connected as described above is called access control. Currently, the term load balancing in cellular systems is often accepted as a connection control technique to achieve a specific purpose.

In an environment where all base stations use the same frequency, due to strong interference from surrounding cells, the access control scheme may be less efficient. In this environment, one of the most used techniques to improve the performance of the system is the beamforming technique. The beamforming technique aims to increase the channel gain for the access base station and reduce the amount of interference from neighboring cells by appropriately adjusting the beamforming vector after installing several antennas on the transmitting side or the receiving side.

In general, these two techniques, connection control and beamforming, have been studied separately.

The connection control technology is a distributed algorithm that generates hand-off by lowering the throughput of a user (terminal) outside the cell or a signal to interference plus noise for each user. various connection methods have been studied for the purpose of satisfying the ratio (SINR) requirement, or for achieving network-wide proportional fairness.

Beamforming techniques have also been proposed for several purposes. Find a beamforming vector that satisfies the specific Signal to Interference Ratio (SIR) requirements for each user, or find a way to select the optimal signal-to-interference ratio allocation, And a method for determining a power setting method have been studied.

It is an object of the present invention to provide an uplink transmission method and a system for selecting a beamforming vector and an access base station based on short-term characteristics of an uplink channel of a mobile communication terminal to further improve system level performance.

In addition, an object of the present invention is to provide an uplink transmission method and a system for improving a system-level performance by selecting a beamforming scheme and an access base station based on an average characteristic of an uplink channel of a mobile communication terminal.

The uplink transmission method according to the present invention includes (a) measuring an average channel and a fading channel between a mobile station and a plurality of candidate base stations on a predetermined time basis, and (b) using the measured channel information, a beam at the mobile station. Selecting a beamforming vector to use for forming and an access base station to be connected to the mobile station from among the plurality of candidate base stations.

(b) step,

를 연산하는 단계, (b-2) 상향링크 전송속도

를 이용하여, 유틸리티 함수 예측 값을 산출하는 단계, 및 (b-3) 유틸리티 함수 예측 값이 최대가 되도록 하는 빔포밍 벡터와 접속 기지국을 선택하는 단계를 포함하고,(b-1) Uplink transmission rate using measured channel information

Calculating (b-2) uplink transmission rate

Calculating a utility function prediction value by using; and (b-3) selecting a beamforming vector and an access base station to maximize the utility function prediction value,

는, 하기의 수식과 같이 표현되며,Uplink transmission rate

Is represented by the following formula,

는, 이동국,

Mobile station,

는, 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

는, 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

Is the channel bandwidth used by the cellular mobile communication system,

는, 이동국

와 기지국

간의 패이딩 채널,

, Mobile station

And base station

Fading channel between,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득,

, Mobile station

And base station

Average channel gain between

는, 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

Is the power of Additive White Gaussian Noise (AWGN),

는, 기지국

이외의 후보 기지국들과 접속한 이동국,

Is a base station

Mobile stations connected to other candidate base stations,

는, 이동국

의 집합,

, Mobile station

Set,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득, 및

, Mobile station

And base station

Average channel gain between, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내고,

Is a mobile station among resources for each of a plurality of candidate base stations

Represents the percentage of resources used by

The utility function is represented by the following formula,

는, 이동국

의 집합,

, Mobile station

Set,

는 상향링크 전송속도, 및

Is the uplink transmission rate, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내는 것이 바람직하다.

Is a mobile station among resources for each of a plurality of candidate base stations

It is desirable to indicate the proportion of resources used by the.

The uplink transmission method according to the present invention comprises (a) controlling a plurality of expected base stations by adjusting the transmission signal strength of a candidate access base station connected to a mobile station and an amount of interference for candidate base stations other than the access candidate base station. Obtaining and storing the gain, (b) measuring the average channel between the mobile station and the plurality of candidate base stations in units of time, and (c) using the expected beamforming gain and average channel information, beamforming at the mobile station And selecting a beamforming vector to use for the first access point and an access base station to be connected to the mobile station among the plurality of candidate base stations.

(a) step,

Expected beamforming gains are obtained by adjusting the transmission signal strength and the amount of interference included in the following equation.

는, 복수의 후보 기지국 중 이동국

와 접속되어 있는 접속후보 기지국,

Is a mobile station among a plurality of candidate base stations

Connected candidate base station,

는, 이동국

와 기지국

간의 패이딩 채널,

, Mobile station

And base station

Fading channel between,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득,

, Mobile station

And base station

Average channel gain between

는, 기지국

이외의 후보 기지국

의 집합,

Is a base station

Candidate base station other than

Set,

는 전송신호세기,

Is the signal strength,

는, 전송신호세기를 조절하기 위한 컨트롤 파라미터,

Is a control parameter for adjusting the transmission signal strength,

는, 이동국

와 후보 기지국

간의 패이딩 채널,

, Mobile station

And candidate base stations

Fading channel between,

는, 이동국

와 후보 기지국

간의 평균 채널 이득,

, Mobile station

And candidate base stations

Average channel gain between

는, 간섭량, 및

Is the amount of interference, and

는, 간섭량을 조절하기 위한 컨트롤 파라미터를 나타내는 것이 바람직하다.

Preferably represents a control parameter for adjusting the amount of interference.

(c) step,

를 연산하는 단계, (c-2) 상향링크 전송속도

를 이용하여, 유틸리티 함수 예측 값을 산출하는 단계, 및 (c-3) 유틸리티 함수 예측 값이 최대가 되도록 하는 빔포밍 벡터와 접속 기지국을 선택하는 단계를 포함하고,(c-1) Uplink transmission rate using a plurality of expected beamforming gains and average channel information

Calculating (c-2) uplink transmission rate

Calculating a utility function prediction value by using; and (c-3) selecting a beamforming vector and an access base station to maximize the utility function prediction value,

는, 하기의 수식과 같이 표현되며,Uplink transmission rate

Is represented by the following formula,

는, 이동국,

Mobile station,

는, 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

는, 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

Is the channel bandwidth used by the cellular mobile communication system,

는, 이동국

와 기지국

간의 패이딩 채널,

, Mobile station

And base station

Fading channel between

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득,

, Mobile station

And base station

Average channel gain between

는, 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

Is the power of Additive White Gaussian Noise (AWGN),

는, 기지국

이외의 후보 기지국들과 접속한 이동국,

Is a base station

Mobile stations connected to other candidate base stations,

는, 이동국

의 집합,

, Mobile station

Set,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득, 및

, Mobile station

And base station

Average channel gain between, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내고,

Is a mobile station among resources for each of a plurality of candidate base stations

Represents the percentage of resources used by

 The utility function is represented by the following formula,

는, 이동국

의 집합,

, Mobile station

Set,

는 상향링크 전송속도, 및

Is the uplink transmission rate, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내는 것이 바람직하다.

Is a mobile station among resources for each of a plurality of candidate base stations

It is desirable to indicate the proportion of resources used by the.

The uplink transmission system according to the present invention may be used for beamforming by using a measuring unit measuring an average channel and a fading channel between a mobile station and a plurality of candidate base stations, and channel information measured by the measuring unit, in predetermined time units. And a selection unit for selecting a beamforming vector and an access base station to be connected to the mobile station among the plurality of candidate base stations.

The selection part,

를 연산하는 연산부, 상향링크 전송속도

를 이용하여, 유틸리티 함수 예측 값을 산출하는 예측부, 및 유틸리티 함수 예측 값이 최대가 되도록 하는 빔포밍 벡터와 접속 기지국을 선택하는 비교 선택부를 포함하고,Uplink transmission rate using channel information measured by the measurement unit

Calculating unit, uplink transmission rate

Using a predictor for calculating a utility function prediction value, and a comparison selecting unit for selecting a beamforming vector and an access base station to maximize the utility function prediction value,

는, 하기의 수식과 같이 표현되며,Uplink transmission rate

Is represented by the following formula,

Mobile station,

는, 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

는, 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

Is the channel bandwidth used by the cellular mobile communication system,

는, 이동국

와 기지국

간의 패이딩 채널,

, Mobile station

And base station

Fading channel between

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득,

, Mobile station

And base station

Average channel gain between

는, 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN) 의 전력,

Is the power of Additive White Gaussian Noise (AWGN),

는, 기지국

이외의 후보 기지국들과 접속한 이동국,

Is a base station

Mobile stations connected to other candidate base stations,

는, 이동국

의 집합,

, Mobile station

Set,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득, 및

, Mobile station

And base station

Average channel gain between, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내고,

Is a mobile station among resources for each of a plurality of candidate base stations

Represents the percentage of resources used by

The utility function is represented by the following formula,

는, 이동국

의 집합,

, Mobile station

Set,

는 상향링크 전송속도, 및

Is the uplink transmission rate, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내는 것이 바람직하다.

Is a mobile station among resources for each of a plurality of candidate base stations

It is desirable to indicate the proportion of resources used by the.

The uplink transmission system according to the present invention adjusts the transmission signal strength of the access candidate base station connected to the mobile station among the plurality of candidate base stations and the amount of interference to the candidate base stations other than the access candidate base station to obtain a plurality of expected beamforming gains. Expected beamforming gain acquisition unit for obtaining and storing, an average channel measuring unit measuring an average channel between the mobile station and the plurality of candidate base stations on a predetermined time basis, and beamforming at the mobile station using the expected beamforming gain and average channel information. And a selection unit for selecting a beamforming vector to be used for the first access point and an access base station to be connected to the mobile station among the plurality of candidate base stations.

The expected beamforming gain acquisition unit,

Obtaining a plurality of expected beamforming gains by adjusting the transmission signal strength and the amount of interference included in the following equation,

는, 복수의 후보 기지국 중 이동국

와 접속되어 있는 접속후보 기지국,

Is a mobile station among a plurality of candidate base stations

Connected candidate base station,

는, 이동국

와 기지국

간의 패이딩 채널,

, Mobile station

And base station

Fading channel between,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득,

, Mobile station

And base station

Average channel gain between

는, 기지국

이외의 후보 기지국

의 집합,

Is a base station

Candidate base station other than

Set,

는 전송신호세기,

Is the signal strength,

는, 전송신호세기를 조절하기 위한 컨트롤 파라미터,

Is a control parameter for adjusting the transmission signal strength,

는, 이동국

와 후보 기지국

간의 패이딩 채널,

, Mobile station

And candidate base stations

Fading channel between

는, 이동국

와 후보 기지국

간의 평균 채널 이득,

, Mobile station

And candidate base stations

Average channel gain between

는, 간섭량, 및

Is the amount of interference, and

는, 간섭량을 조절하기 위한 컨트롤 파라미터를 나타내는 것이 바람직하다.

Preferably represents a control parameter for adjusting the amount of interference.

The selection part,

를 연산하는 연산부, 상향링크 전송속도

를 이용하여, 유틸리티 함수 예측 값을 산출하는 예측부, 및 유틸리티 함수 예측 값이 최대가 되도록 하는 빔포밍 벡터와 접속 기지국을 선택하는 비교 선택부를 포함하고,Multiple uplink transmission rates using multiple expected beamforming gains and average channel information

Calculating unit, uplink transmission rate

Using a predictor for calculating a utility function prediction value, and a comparison selecting unit for selecting a beamforming vector and an access base station to maximize the utility function prediction value,

는, 하기의 수식과 같이 표현되며,Uplink transmission rate

Is represented by the following formula,

는, 이동국,

Mobile station,

는, 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

는, 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

Is the channel bandwidth used by the cellular mobile communication system,

는, 이동국

와 기지국

간의 패이딩 채널,

, Mobile station

And base station

Fading channel between

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득,

, Mobile station

And base station

Average channel gain between

는, 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

Is the power of Additive White Gaussian Noise (AWGN),

는, 기지국

이외의 후보 기지국들과 접속한 이동국,

Is a base station

Mobile stations connected to other candidate base stations,

는, 이동국

의 집합,

, Mobile station

Set,

는, 이동국

에서 사용하는 빔포밍 벡터,

, Mobile station

Beamforming vector used by

는, 이동국

와 기지국

간의 평균 채널 이득, 및

, Mobile station

And base station

Average channel gain between, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내고,

Is a mobile station among resources for each of a plurality of candidate base stations

Represents the percentage of resources used by

The utility function is represented by the following formula,

는, 이동국

의 집합,

, Mobile station

Set,

는 상향링크 전송속도, 및

Is the uplink transmission rate, and

는, 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타내는 것이 바람직하다.

Is a mobile station among resources for each of a plurality of candidate base stations

It is desirable to indicate the proportion of resources used by the.

According to the present invention, it is possible to improve the performance of a cellular mobile communication system by using an efficient method of forming a beam and simultaneously controlling the connection.

Hereinafter, an uplink transmission method and a transmission system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

[Uplink Transmission Method According to First Embodiment]

FIG. 1A is a diagram illustrating an uplink transmission method S100 according to a first embodiment of the present invention. More specifically, it is a diagram for explaining a method of selecting a beamforming vector and an access base station based on short-term fading channel information to increase system-level utility.

Referring to FIG. 1A, the uplink transmission method S100 according to the first embodiment of the present invention includes measuring an average channel and a fading channel between a mobile station and a base station (S110), and selecting a beamforming vector and an access base station (S100). S120).

1. Measuring average channel and fading channel between mobile station and base station (S110)

First, the average channel and the fading channel between the mobile station and the candidate base stations are measured. After the measurement, the timer T1 may be operated to check whether the timer has expired. At this time, when the timer T1 has expired, the measured process may proceed to step S120 for selecting a beamforming vector and access base station by using the measured average channel information and fading channel information. On the other hand, if the timer T1 does not expire, the average channel and the fading channel between the mobile station and the base station can be measured again. As described above, in step S110, the average channel and the fading channel between the mobile station and the candidate base stations can be measured in a predetermined time unit T1.

2. Beamforming vector and access base station selection step (S120)

FIG. 1B is a diagram illustrating the beamforming vector and access base station selection step S120 illustrated in FIG. 1A.

In the beamforming vector and access base station selection step (S120), the beamforming vector to be used for forming a beam in the mobile station and the access base station to be connected to the mobile station can be selected from among the plurality of candidate base stations using the channel information measured in step S110. have.

Referring to FIG. 1B, the beamforming vector and the access base station selection step S120 include an uplink transmission rate calculation step S121, a utility function prediction value calculation step S123, and a beam that maximizes the utility function prediction value. A forming vector and access base station selection step S125 are included.

2-1) Uplink transmission rate calculation step (S121)

를 연산할 수 있다. 여기서, 상향링크 전송속도

는, 여러 기지국(후보 기지국)들이 존재하는 셀룰러 이동통신 시스템 환경에서 이동국과 접속한 접속 기지국에 대한 전송속도를 의미하며, 수식은 하기와 같이 표현할 수 있다.In the uplink transmission rate calculating step (S121), an uplink transmission rate for calculating a utility function prediction value based on the average channel and the fading channel information measured in step S110.

Can be calculated. Where uplink transmission rate

Denotes a transmission rate for an access base station connected with a mobile station in a cellular mobile communication system environment in which several base stations (candidate base stations) exist, and the equation may be expressed as follows.

는 이동국,

는 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

는 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

는 이동국

와 기지국

간의 패이딩 채널,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득,

는 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

는 기지국

이외의 후보 기지국들과 접속한 이동국,

는 이동국

의 집합,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득, 및

는 복수 의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Is a mobile station,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Mobile station

And base station

Fading channel between,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is a base station

Mobile stations connected to other candidate base stations,

Mobile station

Set,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

를 얻을 수 있다.As described above, in the uplink transmission rate calculating step (S121), various uplink transmission rates for the candidate base stations are obtained using the average channel and the fading channel information between the mobile station and the candidate base stations measured in a predetermined time unit (T1).

Can be obtained.

2-2) Utility Function Prediction Value Calculation Step (S123)

In calculating the utility function prediction value (S123), utility function values of the system according to the beamforming vector and the access base station may be predicted using the uplink transmission rate. Utility functions can be expressed as in the following equation.

는 이동국

의 집합,

는 상향링크 전송속도, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

2-3) step of selecting a beamforming vector and access base station to maximize the utility function prediction value (S125)

를 바탕으로, 유틸리티 함수 값을 가장 크게 높일 수 있는 접속 기지국과 빔형성 벡터를 선택할 수 있다. 즉, 산출된 유틸리티 함수 예측 값 중 가장 큰 예측 값을 갖도록 하는 상향링크 전송속도

를 찾고, 그 상향링크 전송속도

를 연산하기 위해 적용된 빔포밍 벡터

와 접속 기지국을 선택할 수 있다. 결국, 시스템 수준의 유틸리티를 가장 크게 높일 수 있는 빔포밍 벡터와 접속 기지국을 선택할 수 있게 된다.In step S125, the predicted uplink transmission rate

Based on the above, it is possible to select an access base station and a beamforming vector that can greatly increase the utility function value. That is, the uplink transmission rate that has the largest prediction value among the calculated utility function prediction values

To find the uplink transmission rate

Beamforming vector applied to compute

And access base station can be selected. As a result, it is possible to select beamforming vectors and access base stations that can greatly increase system-level utility.

1C is a diagram illustrating a comparison of system utility values when transmitting signals according to the conventional uplink transmission method S10 and the uplink transmission method S100 according to the first embodiment of the present invention.

The graph of the conventional uplink transmission method (S10) shown in FIG. In this case, the log of the throughput of the mobile stations is shown and the sum is shown.

As shown in FIG. 1C, the first embodiment of the present invention is compared with the conventional uplink transmission method (S10) in which a beam is formed without considering the candidate base station and system level utility and the access base station is selected. When the signal is transmitted according to the uplink transmission method according to S100, it can be seen that the utility value of the system level increases.

[Uplink Transmission Method According to Second Embodiment]

If the above-described uplink transmission method of the first embodiment relates to a beamforming technique and a method of selecting an access base station based on an instantaneous channel state, the uplink transmission method of the second embodiment provides a method for reducing overhead of beamforming. The present invention relates to a beamforming technique and a method for selecting an access base station based on an average channel state.

2A is a diagram illustrating an uplink transmission method S200 according to a second embodiment of the present invention.

Referring to FIG. 2A, the uplink transmission method S200 according to the second embodiment of the present invention includes obtaining and storing an expected beamforming gain (S210), an average channel measuring step (S220), and a beamforming vector and connection. A base station selection step S230 is included.

1. Obtain and store the expected beamforming gain (S210)

In the obtaining and storing the expected beamforming gain (s210), the expected beamforming gain for each of the various beamforming methods may be obtained and stored. In this case, the beamforming methods have different values for the gain value of the signal strength for the access base station and the interference value for the candidate base station, and the beamforming gains expected when using a specific method for obtaining the values should be different from each other. do. To this end, various beamforming gains may be obtained using finite beamforming methods, and beamforming methods for obtaining the gain based on the similarity may be selected and defined as a set. Here, the beamforming methods defined as a set mean beamforming methods as candidates which can be used among a number of beamforming methods.

Hereinafter, the obtaining and storing the expected beamforming gain (s210) will be described in more detail.

FIG. 2B is a diagram illustrating the expected beamforming acquisition and storage step S210 of FIG. 2A.

Referring to FIG. 2B, the expected beamforming obtaining and storing step S210 may include obtaining and storing a plurality of expected beamforming gains for various beamforming methods S211, and an expected beam having a low similarity among the expected beamforming gains. In step S213, the method for obtaining the forming gain is selected as an available candidate beamforming method.

1-1) Acquiring and storing a plurality of expected beamforming gains (S211)

Acquiring and storing a plurality of expected beamforming gains (S211), a plurality of expected beamforming gains are obtained by adjusting transmission signal strengths for base stations connected to the mobile station and interference values for candidate base stations other than the access candidate base stations. Can be stored.

As described above, various methods may be used to define a large number of beamforming methods. For example, various expected beamforming gains may be calculated through the beamforming method represented by the following equation.

는 복수의 후보 기지국 중 이동국

와 접속되어 있는 접속후보 기지국,

는 이동국

와 기지국

간의 패이딩 채널,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득,

는 기지국

이외의 후보 기지국

의 집합,

는 전송신호세기,

는 전송신호세기를 조절하기 위한 컨트롤 파라미터,

는 이동국

와 후보 기지국

간의 패이딩 채널,

는 이동국

와 후보 기지국

간의 평균 채널 이득,

는 간섭량, 및

는 간섭량을 조절하기 위한 컨트롤 파라미터를 나타낸다.

Is a mobile station among a plurality of candidate base stations

Connected candidate base station,

Mobile station

And base station

Fading channel between,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between

Is a base station

Candidate base station other than

Set,

Is the signal strength,

Is a control parameter for adjusting the transmission signal strength,

Mobile station

And candidate base stations

Fading channel between,

Mobile station

And candidate base stations

Average channel gain between

Is the amount of interference, and

Denotes a control parameter for adjusting the amount of interference.

값 중에서 argmax 안에 있는 값이 최대가 되도록 하는

를 선택하는 동작을 나타낸 것이다. argmax 안의 수식에서 h와 g는 주어진 값이며, w는 argmax 라는 동작을 통해 얻어지는 값이 된다. 따라서, 각각의 q 값들은 argmax 식 안의 값 자체를 변화시킬 수 있는 파라미터가 될 수 있다. 이에 따라 q 값을 조절하여 argmax 수식 안의 값을 바꿔줌으로써, 어느 기지국으로의 성능을 더 고려할 것인지를 결정할 수 있다. argmax 수식 안의 값이 커지기 위해서는 앞부분인 전송신호세기

의 값이 커지거나, 뒷부분인 간섭량

의 값이 커져야 한다.Equation 3 is selectable

To maximize the value within argmax

It shows the operation of selecting. In the expression in argmax, h and g are given values, and w is the value obtained through the operation argmax. Thus, each q value can be a parameter that can change the value in the argmax expression itself. Accordingly, by adjusting the q value to change the value in the argmax equation, it is possible to determine which base station performance to consider more. In order to increase the value in argmax expression,

Increases the value of, or the amount of interference later

Must be large.

를 선택했을 경우, 접속후보 기지국

에 대한 전송신호세기

값에

값을 곱한 값이 되며, 뒷부분은

가 정해졌을 때 후보 기지국

에 대한 간섭량

에

값을 곱한 값이 된다. 따라서,

값을 크게 설정할 경우, 전송신호세기

값을 조금만 높여도 argmax 수식 안의 값이 매우 커지게 되므로, 신호전송세기를 높여주기 위한

를 선택하는 결과가 나오게 된다. 즉, 간섭량이 증가하더라도

를 큰 값으로 설정하였기 때문에, 간섭량은 크게 중요하지 않다는 것을 의미한다. 따라서, 간섭량이 조금 증가하는 상황이라도 전송신호세기만을 조금 더 크게 만들 수 있는

를 선택할 수 있다. 반면,

가 0이라고 가정할 경우, 전송신호세기

를 아무리 증가시키더라도 argmax 수식 내의 값이 커지지 않으므로, 간섭량을 최대한 줄여서 argmax 수식 내의 값이 커지도록 하는 를 선택할 수 있다.In Equation 3, the first part of the argmax expression

If you select, the candidate base station for connection

Signal strength for

To the value

Is multiplied by the value,

Candidate base station when

Interference amount for

on

It is multiplied by the value. therefore,

If you set a large value, the transmission signal strength

Increasing the value slightly increases the value in the argmax formula, so it is necessary to increase the signal transmission strength.

The result is that you select. That is, even if the amount of interference increases

Since is set to a large value, it means that the amount of interference is not very important. Therefore, even in a situation where the amount of interference increases slightly, only the signal strength can be made slightly larger.

Can be selected. On the other hand,

If is assumed to be 0, the signal strength

Since increasing the value does not increase the value in the argmax equation, we can choose to reduce the amount of interference as much as possible to increase the value in the argmax equation.

와

를 조절하여, 다양한 기대 빔포밍 이득을 획득하고 저장할 수 있다.In this sense, each q value calculated for each base station state may be a parameter indicating how much to consider the transmission signal strength or the amount of interference. therefore,

Wow

Can be adjusted to obtain and store various expected beamforming gains.

1-2) candidate beamforming method selection step (S213)

와 접속 기지국

에 대한 집합도 정의될 수 있다.In the candidate beamforming method selection step (S213), the candidate beamforming method is selected by selecting an expected beamforming gain having a low similarity among the obtained expected beamforming gains. That is, the beamforming method used to calculate the selected expected beamforming gain may be selected as the candidate beamforming method. Therefore, the selected candidate beamforming methods may be defined as a set. Also, beamforming vector to be used for beam forming

And access base station

A set of can also be defined.

2. Average Channel Measurement Step (S220)

In the average channel measurement step S220, the average channel between the mobile station and the candidate base stations is measured. After the measurement, the timer T1 may be operated to check whether the timer has expired. At this time, when the timer T2 has expired, it may proceed to step S230 for selecting a next beamforming vector and access base station by using the measured average channel information. On the other hand, if the timer T2 does not expire, the average channel and the fading channel between the mobile station and the base station can be measured again. As such, in step S220, the average channel between the mobile station and the candidate base stations may be measured in a predetermined time unit T2.

3. Beamforming vector and access base station selection step (S230)

FIG. 2C is a diagram illustrating the beamforming vector and access base station selection step S230 illustrated in FIG. 2A.

In the beamforming vector and access base station selection step (S230), the beamforming vector to be used for forming a beam in the mobile station and the access base station to be connected to the mobile station among the plurality of candidate base stations are determined using the average channel information measured in step S220. You can choose.

Referring to FIG. 2C, the beamforming vector and access base station selection step (S230) include an uplink transmission rate calculation step (S231), a utility function prediction value calculation step (S233), and a beam that maximizes the utility function prediction value. Forming vector and access base station selection step (S235).

3-1) Uplink transmission rate calculation step (S231)

를 연산할 수 있다. 여기서, 상향링크 전송속도

는, 여러 기지국(후보 기지국)들이 존재하는 셀룰러 이동통신 시스템 환경에서 이동국과 접속한 접속 기지국에 대한 전송속도를 의미하며, 수식은 하기와 같이 표현할 수 있다.In the uplink transmission rate calculating step (S121), the uplink transmission rate is calculated in order to calculate a utility function prediction value based on the average channel information measured in step S220 and the expected beamforming gain obtained in step S210.

Can be calculated. Where uplink transmission rate

Denotes a transmission rate for an access base station connected with a mobile station in a cellular mobile communication system environment in which several base stations (candidate base stations) exist, and the equation may be expressed as follows.

는 이동국,

는 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

는 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

는 이동국

와 기지국

간의 패이딩 채널,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득,

는 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

는 기지국

이외의 후보 기지국들과 접속한 이동국,

는 이동국

의 집합,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸 다.

Is a mobile station,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Mobile station

And base station

Fading channel between

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is a base station

Mobile stations connected to other candidate base stations,

Mobile station

Set,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between, and

Is a mobile station among resources for each of a plurality of candidate base stations

Shows the proportion of resources used by

를 얻을 수 있다.As described above, in the uplink transmission rate calculating step (S231), various uplink transmission rates for the candidate base stations are obtained by using the average channel information and the expected beamforming gain between the mobile station and the candidate base stations measured in a predetermined time unit (T2).

Can be obtained.

3-2) Utility Function Prediction Value Calculation Step (S233)

를 이용하여, 빔포밍 벡터와 접속 기지국에 따른 시스템의 유틸리티 함수 값들을 예측할 수 있다. 유틸리티 함수는 하기의 수식과 같이 표현할 수 있다.In the utility function prediction value calculation step (S233), the uplink transmission rate

By using, it is possible to predict the utility function values of the system according to the beamforming vector and the access base station. Utility functions can be expressed as in the following equation.

는 이동국

의 집합,

는 상향링크 전송속도, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

3-3) step of selecting a beamforming vector and access base station to maximize the utility function prediction value (S235)

를 바탕으로 유틸리티 함수 값을 가장 크게 높일 수 있는 접속 기지국과 빔형성 벡터를 선택할 수 있다. 즉, 산출된 유틸리티 함수 예측 값 중 가장 큰 예측 값을 갖도록 한 상향링크 전송속도

를 찾고, 그 상향링크 전송속도

에 적용된 빔포밍 벡터

와 접속 기지국을 선택할 수 있다. 결국, 시스템 수준의 유틸리티를 가장 크게 높일 수 있는 빔포밍 벡터와 접속 기지국을 선택할 수 있게 된다.In step S235, the estimated uplink transmission rate

Based on this, the access base station and the beamforming vector that can maximize the utility function value can be selected. That is, the uplink transmission rate that has the largest prediction value among the calculated utility function prediction values

To find the uplink transmission rate

Beamforming Vector Applied to

And access base station can be selected. As a result, it is possible to select beamforming vectors and access base stations that can greatly increase system-level utility.

2D is a diagram illustrating a comparison of system utility values when transmitting signals according to the conventional uplink transmission method S20 and the uplink transmission method S200 according to the second embodiment of the present invention.

The graph of the conventional uplink transmission method S20 shown in FIG. Their throughput is shown as a log of the throughput.

As shown in FIG. 2D, the second embodiment of the present invention is compared to the conventional uplink transmission method S20 in which a beam is formed without considering the candidate base station and system level utility and the access base station is selected. When the signal is transmitted according to the uplink transmission method (S200), it can be seen that the utility value of the system level increases.

[Transmission system according to the first embodiment]

Hereinafter, a transmission system for executing the uplink transmission method of the first embodiment will be described.

3 is a diagram illustrating a configuration of an uplink transmission system 300 for executing an uplink transmission method according to a first embodiment of the present invention.

Referring to FIG. 3, the uplink transmission system 300 according to the first embodiment of the present invention includes a measuring unit 310 and a selecting unit 320.

1. Measuring unit 310

The measurement unit 310 may measure an average channel and a fading channel between the mobile station and the plurality of candidate base stations. In addition, the measurement unit 310 may check whether the timer has expired by operating the timer T1 after measuring the channel. At this time, when the timer T1 expires, the selector 320 starts using the measured average channel information and fading channel information. On the other hand, if the timer T1 does not expire, the average channel and the fading channel between the mobile station and the base station can be measured again. As such, the measurement unit 310 may measure the average channel and the fading channel between the mobile station and the candidate base stations in a predetermined time unit T1.

2. Selection part 320

The selector 320 may select a beamforming vector to be used for beamforming and an access base station to be connected to the mobile station among a plurality of candidate base stations based on the channel information measured by the measurement unit 310.

The selector 320 may include a calculator 321, a predictor 323, and a comparison selector 325.

2-1) Computing Unit 321

를 연산할 수 있다. 여기서, 상향링크 전송속도

는 여러 기지국(후보 기지국)들이 존재하는 셀룰러 이동통신 시스템 환경에서 이동국과 접속한 접속 기지국에 대한 전송속도를 의미하며, 수식은 하기와 같이 표현할 수 있다.The calculator 321 may calculate an uplink transmission rate for calculating a utility function prediction value based on the channel information measured by the measurer 310.

Can be calculated. Where uplink transmission rate

Denotes a transmission rate for an access base station connected to a mobile station in a cellular mobile communication system environment in which several base stations (candidate base stations) exist, and the equation may be expressed as follows.

는 이동국,

는 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지국,

는 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

는 이동국

와 기지국

간의 패이딩 채널,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득,

는 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

는 기지국

이외의 후보 기지국들과 접속한 이동국,

는 이동국

의 집합,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Is a mobile station,

Is a mobile station among a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Mobile station

And base station

Fading channel between,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is a base station

Mobile stations connected to other candidate base stations,

Mobile station

Set,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

를 얻을 수 있다.As such, the selector 320 may use various uplink transmission rates for the candidate base stations using average channel and padding channel information between the mobile station and the candidate base stations measured in a predetermined time unit (T1).

Can be obtained.

2-2) Predictor 323

를 이용하여, 빔포밍 벡터와 접속 기지국에 따른 시스템의 유틸리티 함수 값들을 예측할 수 있다. 유틸리티 함수는 하기의 수식과 같이 표현할 수 있다.Prediction unit 323 uplink transmission rate

By using, it is possible to predict the utility function values of the system according to the beamforming vector and the access base station. Utility functions can be expressed as in the following equation.

는 이동국

의 집합,

는 상향링크 전송속도, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

2-3) comparison selection unit 325

를 바탕으로 유틸리티 함수 값을 가장 크게 높일 수 있는 접속 기지국과 빔형성 벡터를 선택할 수 있다. 즉, 산출된 유틸리티 함수 예측 값 중 가장 큰 예측 값을 갖도록 하는 상향링크 전송속도

를 찾고, 그 상향링크 전송속도

를 연산하기 위해 적용된 빔포밍 벡터

와 접속 기지국을 선택할 수 있다. 결국, 시스템 수준의 유틸리티를 가장 크게 높일 수 있는 빔포밍 벡터와 접속 기지국을 선택할 수 있게 된다.The comparison selector 325 may select a beamforming vector and an access base station to maximize the utility function prediction value. That is, the comparison selector 325 predicts the uplink transmission rate.

Based on this, the access base station and the beamforming vector that can maximize the utility function value can be selected. That is, the uplink transmission rate that has the largest prediction value among the calculated utility function prediction values

To find the uplink transmission rate

Beamforming vector applied to compute

And access base station can be selected. As a result, it is possible to select beamforming vectors and access base stations that can greatly increase system-level utility.

[Transmission system according to the second embodiment]

Hereinafter, a transmission system for executing the uplink transmission method of the second embodiment will be described.

4 is a diagram illustrating a configuration of an uplink transmission system for executing an uplink transmission method according to a second embodiment of the present invention.

Referring to FIG. 4, the uplink transmission system 400 according to the second embodiment of the present invention includes an expected beamforming gain acquirer 410, an average channel measurer 420, and a selector 430. do.

1. Expected beamforming gain acquisition unit 410

The expected beamforming gain obtaining unit 410 may obtain and store a plurality of expected beamforming gains by adjusting a transmission signal strength for a base station connected to a mobile station and interference values for candidate base stations other than the connected candidate base station. . That is, it is possible to obtain and store the expected beamforming gain for each of the various beamforming methods. In this case, the beamforming methods may have different gain values of the signal strength for the access base station and different beamforming gains expected when using a specific method for obtaining the values after obtaining various values for the interference value for the candidate base station. do. To this end, various beamforming gains may be obtained using finite beamforming methods, and beamforming methods for obtaining the gain based on the similarity may be selected and defined as a set. Here, the beamforming methods defined as a set mean beamforming methods that can be used as candidates among a number of beamforming methods.

Hereinafter, the expected beamforming gain acquisition unit 410 will be described in more detail.

First, a plurality of expected beamforming gains may be obtained and stored by adjusting a transmission signal strength for a base station connected to a mobile station and interference values for candidate base stations other than the access candidate base station.

As described above, various methods may be used to define a number of beamforming methods. For example, various expected beamforming gains may be calculated through the beamforming method represented by the following equation.

는 복수의 후보 기지국 중 이동국

와 접속되어 있는 접속후보 기지국,

는 이동국

와 기지국

간의 패이딩 채널,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득,

는 기지국

이외의 후보 기지국

의 집합,

는 전송신호세기,

는 전송신호세기를 조절하기 위한 컨트롤 파라미터,

는 이동국

와 후보 기지국

간의 패이딩 채널,

는 이동국

와 후보 기지국

간의 평균 채널 이득,

는 간섭량, 및

는 간섭량을 조절하기 위한 컨트롤 파라미터를 나타낸다.

Is a mobile station among a plurality of candidate base stations

Connected candidate base station,

Mobile station

And base station

Fading channel between

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between

Is a base station

Candidate base station other than

Set,

Is the signal strength,

Is a control parameter for adjusting the transmission signal strength,

Mobile station

And candidate base stations

Fading channel between

Mobile station

And candidate base stations

Average channel gain between

Is the amount of interference, and

Denotes a control parameter for adjusting the amount of interference.

값 중에서 argmax 안에 있는 값이 최대가 되도록 하는

를 선택하는 동작을 나타낸 것이다. argmax 안의 수식에서 h와 g는 주 어진 값이며, w는 argmax 라는 동작을 통해 얻어지는 값이 된다. 따라서, 각각의 q 값들은 argmax 식 안의 값 자체를 변화시킬 수 있는 파라미터가 될 수 있다. 이에 따라 q 값을 조절하여 argmax 수식 안의 값을 바꿔줌으로써, 어느 기지국으로의 성능을 더 고려할 것인지를 결정할 수 있다. argmax 수식 안의 값이 커지기 위해서는 앞부분인 전송신호세기

의 값이 커지거나, 뒷부분인 간섭량

의 값이 커져야 한다.Equation 8 is selectable

To maximize the value within argmax

It shows the operation of selecting. In the formula in argmax, h and g are given values, and w is the value obtained through the operation argmax. Thus, each q value can be a parameter that can change the value in the argmax expression itself. Accordingly, by adjusting the q value to change the value in the argmax equation, it is possible to determine which base station performance to consider more. In order to increase the value in argmax expression,

Increases the value of, or the amount of interference later

Must be large.

를 선택했을 경우, 접속후보 기지국

에 대한 전송신호세기

값에

값을 곱한 값이 되며, 뒷부분은

가 정해졌을 때 후보 기지국

에 대한 간섭량

에

값을 곱한 값이 된다. 따라서,

값을 크게 설정할 경우, 전송신호세기

값을 조금만 높여도 argmax 수식 안의 값이 매우 커지게 되므로, 신호전송세기를 높여주기 위한

를 선택하는 결과가 나오게 된다. 즉, 간섭량이 증가하더라도

를 큰 값으로 설정하였기 때문에, 간섭량은 크게 중요하지 않다는 것을 의미한다. 따라서, 간섭량이 조금 증가하는 상황이라도 전송신호세기만을 조금 더 크게 만들 수 있는

를 선택할 수 있다. 반면,

가 0이라고 가정할 경 우, 전송신호세기

를 아무리 증가시키더라도 argmax 수식 내의 값이 커지지 않으므로, 간섭량을 최대한 줄여서 argmax 수식 내의 값이 커지도록 하는 를 선택할 수 있다.In Equation 8, the first part of the argmax expression

If you select, the candidate base station for connection

Signal strength for

To the value

Is multiplied by the value,

Candidate base station when

Interference amount for

on

It is multiplied by the value. therefore,

If you set a large value, the transmission signal strength

Increasing the value slightly increases the value in the argmax formula, so it is necessary to increase the signal transmission strength.

The result is that you select. That is, even if the amount of interference increases

Since is set to a large value, it means that the amount of interference is not very important. Therefore, even in a situation where the amount of interference increases slightly, only the signal strength can be made slightly larger.

Can be selected. On the other hand,

Assuming 0 is 0, signal strength

Since increasing the value does not increase the value in the argmax equation, we can choose to reduce the amount of interference as much as possible to increase the value in the argmax equation.

와

를 조절하여, 다양한 기대 빔포밍 이득을 획득하고 저장할 수 있다.In this sense, each q value calculated for each base station state may be a parameter indicating how much to consider the transmission signal strength or the amount of interference. therefore,

Wow

Can be adjusted to obtain and store various expected beamforming gains.

와 접속 기지국

에 대한 집합도 정의할 수 있게 된다.Next, the candidate beamforming method may be selected by selecting an expected beamforming gain having a low similarity among the obtained expected beamforming gains. That is, the beamforming method used to calculate the selected expected beamforming gain may be selected as the candidate beamforming method. Therefore, the selected candidate beamforming methods may be defined as a set. Also, beamforming vector to be used for beam forming

And access base station

You can also define a set of.

2. Average channel measurement unit 420

The average channel measurer 420 may measure an average channel between the mobile station and the candidate base stations. After the measurement, the timer T1 may be operated to check whether the timer has expired. At this time, when the timer T2 has expired, the selector 430 operates. On the other hand, if the timer T2 does not expire, the average channel and the fading channel between the mobile station and the base station can be measured again. As described above, the average channel measuring unit 420 may measure the average channel between the mobile station and the candidate base stations in a predetermined time unit T2.

3. Selector 430

Referring to FIG. 4, the selector 430 may include an operation unit 431, a predictor 433, and a comparison selector 435.

3-1) Computing Unit 431

를 연산할 수 있다. 여기서, 상향링크 전송속도

는 여러 기지국(후보 기지국)들이 존재하는 셀룰러 이동통신 시스템 환경에서 이동국과 접속한 접속 기지국에 대한 전송속도를 의미하며, 수식은 하기와 같이 표현할 수 있다.The calculating unit 431 uses a plurality of expected beamforming gains and average channel information to transmit a plurality of uplink transmission rates.

Can be calculated. Where uplink transmission rate

Denotes a transmission rate for an access base station connected to a mobile station in a cellular mobile communication system environment in which several base stations (candidate base stations) exist, and the equation may be expressed as follows.

는 이동국,

는 복수의 후보 기지국 중 이동국

와 접속되어 있는 기지 국,

는 셀룰러 이동통신 시스템에서 사용하는 채널 대역폭,

는 이동국

와 기지국

간의 패이딩 채널,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득,

는 부가적인 백색 가우시안 잡음(Additive White Gaussian Noise, AWGN)의 전력,

는 기지국

이외의 후보 기지국들과 접속한 이동국,

는 이동국

의 집합,

는 이동국

에서 사용하는 빔포밍 벡터,

는 이동국

와 기지국

간의 평균 채널 이득, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Is a mobile station,

Is a mobile station among a plurality of candidate base stations

Base station connected with

Is the channel bandwidth used by the cellular mobile communication system,

Mobile station

And base station

Fading channel between

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is a base station

Mobile stations connected to other candidate base stations,

Mobile station

Set,

Mobile station

Beamforming vector used by

Mobile station

And base station

Average channel gain between, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

를 얻을 수 있다.As described above, the calculation unit 431 uses the average channel information and the expected beamforming gain between the mobile station and the candidate base stations measured in a predetermined time unit T2, and thus, various uplink transmission rates for the candidate base stations.

Can be obtained.

3-2) Prediction Unit 433

를 이용하여 다양한 유틸리티 함수 예측 값들을 산출할 수 있다. 유틸리티 함수는 하기의 수식과 같이 표현할 수 있다.The prediction unit 433 is an uplink transmission rate obtained through the calculation unit 431.

Various utility function prediction values may be calculated using. Utility functions can be expressed as in the following equation.

는 이동국

의 집합,

는 상향링크 전송속도, 및

는 복수의 후보 기지국 각각에 대한 자원 중 이동국

가 사용하는 자원의 비율을 나타낸다.

Mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of a plurality of candidate base stations

Indicates the percentage of resources used by

3-3) Comparison Selector 435

를 찾고, 그 상향링크 전송속도

에 적용된 빔포밍 벡터

와 접속 기지국을 선택할 수 있다. 결국, 시스템 수준의 유틸리티를 가장 크게 높일 수 있는 빔포밍 벡터와 접속 기지국을 선택할 수 있게 된다.The comparison selector 435 may select the beamforming vector and the access base station to maximize the utility function prediction value. That is, the uplink transmission rate that has the largest prediction value among the calculated utility function prediction values

To find the uplink transmission rate

Beamforming Vector Applied to

And access base station can be selected. As a result, it is possible to select beamforming vectors and access base stations that can greatly increase system-level utility.

As described above, those skilled in the art to which the present invention pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the following claims rather than the above description, and the meaning and scope of the claims And it should be construed that all changes or modifications derived from the equivalent concept are included in the scope of the present invention.

1A is a diagram illustrating an uplink transmission method S100 according to a first embodiment of the present invention.

FIG. 1B is a diagram for explaining the beamforming vector and access base station selection step S120 shown in FIG. 1A; FIG.

Figure 1c is a view showing a comparison of the system utility value in the signal transmission according to the conventional uplink transmission method (S10) and the uplink transmission method (S100) according to the first embodiment of the present invention.

Figure 2a is a view showing for explaining an uplink transmission method (S200) according to a second embodiment of the present invention.

FIG. 2B is a diagram for explaining the expected beamforming acquisition and storage step S210 shown in FIG. 2A; FIG.

FIG. 2C is a diagram for explaining the beamforming vector and access base station selection step S230 shown in FIG. 2A; FIG.

Figure 2d is a view showing a comparison of the system utility value when transmitting a signal according to the conventional uplink transmission method (S20) and the uplink transmission method (S200) according to a second embodiment of the present invention.

3 is a diagram illustrating a configuration of an uplink transmission system for executing an uplink transmission method according to a first embodiment of the present invention.

4 is a diagram illustrating a configuration of an uplink transmission system for executing an uplink transmission method according to a second embodiment of the present invention.

Claims (10)

A method for uplink transmission by mobile stations using beamforming and access control in a cellular mobile communication system, (a) measuring an average channel and a fading channel between the mobile station and the plurality of candidate base stations on a predetermined time basis; And (b) using the measured channel information, selecting a beamforming vector to be used for beamforming in a mobile station, and an access base station to be connected to the mobile station among the plurality of candidate base stations; In step (b), (b-1) Uplink transmission rate using the measured channel information

Calculating a; (b-2) the uplink transmission rate

Calculating a utility function prediction value using; And (b-3) selecting a beamforming vector and an access base station to maximize the utility function prediction value. The method of claim 1, The uplink transmission rate

Is represented by the following formula,

Mobile station,

Is a mobile station of a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Is the mobile station

And the base station

Fading channel between

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is the base station

Mobile stations connected to other candidate base stations,

Is the mobile station

Set,

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between, and

Is the mobile station among resources for each of the plurality of candidate base stations

Represents the percentage of resources used by The utility function is expressed as in the following formula,

Is the mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of the plurality of candidate base stations

Uplink transmission method indicating the ratio of resources used by the. A method for uplink transmission by mobile stations using beamforming and access control in a cellular mobile communication system, (a) acquiring and storing a plurality of expected beamforming gains by adjusting a transmission signal strength for a connected candidate base station connected to a mobile station among a plurality of candidate base stations and an interference amount for a candidate base station other than the connected candidate base station; (b) measuring an average channel between the mobile station and the plurality of candidate base stations in units of time; And (c) using the expected beamforming gain and the average channel information, selecting a beamforming vector to be used for beamforming in a mobile station and an access base station to be connected to the mobile station among the plurality of candidate base stations; Way. The method of claim 3, In step (a), The expected beamforming gain is obtained by adjusting a plurality of the transmission signal strength and the amount of interference included in the following equation,

Is a mobile station of a plurality of candidate base stations

Connected candidate base station,

Is the mobile station

And the base station

Fading channel between

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between

Is the base station

Candidate base station other than

Set,

Is the transmission signal strength,

Is a control parameter for adjusting the transmission signal strength,

Is the mobile station

And the candidate base station

Fading channel between

Is the mobile station

And the candidate base station

Average channel gain between

Is the amount of interference, and

Is a control parameter for adjusting the amount of interference, uplink transmission method. 5. The method of claim 4, In step (c), (c-1) an uplink transmission rate using the plurality of expected beamforming gains and the average channel information

Calculating a; (c-2) the uplink transmission rate

Calculating a utility function prediction value using; And (c-3) selecting a beamforming vector and an access base station to maximize the utility function prediction value, The uplink transmission rate

Is represented by the following formula,

Mobile station,

Is a mobile station of a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Is the mobile station

And the base station

Fading channel between

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is the base station

Mobile stations connected to other candidate base stations,

Is the mobile station

Set,

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between, and

Is the mobile station among resources for each of the plurality of candidate base stations

Represents the percentage of resources used by The utility function is expressed as in the following formula,

Is the mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of the plurality of candidate base stations

Uplink transmission method indicating the ratio of resources used by the. An uplink transmission system in a mobile station for uplink transmission using beamforming and access control in a cellular mobile communication system, A measurement unit measuring a mean channel and a fading channel between the mobile station and the plurality of candidate base stations on a predetermined time basis; And Using a channel information measured by the measurement unit, a beamforming vector to be used for beamforming, and a selection unit for selecting an access base station to be connected to a mobile station among the plurality of candidate base stations; The selection unit, Uplink transmission rate using the channel information measured by the measuring unit

A calculation unit for calculating a; The uplink transmission rate

A prediction unit that calculates a utility function prediction value using a; And And a comparison selector for selecting a beamforming vector and an access base station to maximize the utility function prediction value. The method of claim 6, The uplink transmission rate

Is represented by the following formula,

Mobile station,

Is a mobile station of a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Is the mobile station

And the base station

Fading channel between

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is the base station

Mobile stations connected to other candidate base stations,

Is the mobile station

Set,

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between, and

Is the mobile station among resources for each of the plurality of candidate base stations

Represents the percentage of resources used by The utility function is expressed as in the following formula,

Is the mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of the plurality of candidate base stations

Uplink transmission system indicating a ratio of resources used by the. An uplink transmission system in a mobile station for uplink transmission using beamforming and access control in a cellular mobile communication system, Acquiring an expected beamforming gain for obtaining and storing a plurality of expected beamforming gains by adjusting a transmission signal strength for a connection candidate base station connected to a mobile station among a plurality of candidate base stations and an interference amount for a candidate base station other than the access candidate base station. part; An average channel measuring unit measuring an average channel between the mobile station and the plurality of candidate base stations on a predetermined time basis; And And a selecting unit for selecting a beamforming vector to be used for beamforming in a mobile station and an access base station to be connected to the mobile station among the plurality of candidate base stations, using the expected beamforming gain and the average channel information. The method of claim 8, The expected beamforming gain acquisition unit, Obtaining a plurality of expected beamforming gains by adjusting the transmission signal strength and the amount of interference included in the following equation,

Is a mobile station of a plurality of candidate base stations

Candidate candidate station connected to

Is the mobile station

And the base station

Fading channel between

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between

Is the base station

Candidate base station other than

Set,

Is the transmission signal strength,

Is a control parameter for adjusting the transmission signal strength,

Is the mobile station

And the candidate base station

Fading channel between

Is the mobile station

And the candidate base station

Average channel gain between

Is the amount of interference, and

Indicates an control parameter for adjusting the amount of interference. 10. The method of claim 9, The selection unit, A plurality of uplink transmission rates using the plurality of expected beamforming gains and the average channel information

A calculation unit for calculating a; The uplink transmission rate

A prediction unit that calculates a utility function prediction value using a; And A comparison selection unit for selecting a beamforming vector and an access base station to maximize the utility function prediction value, The uplink transmission rate

Is represented by the following formula,

Mobile station,

Is a mobile station of a plurality of candidate base stations

A base station connected to the

Is the channel bandwidth used by the cellular mobile communication system,

Is the mobile station

And the base station

Fading channel between

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between

Is the power of Additive White Gaussian Noise (AWGN),

Is the base station

Mobile stations connected to other candidate base stations,

Is the mobile station

Set,

Is the mobile station

Beamforming vector used by

Is the mobile station

And the base station

Average channel gain between, and

Is the mobile station among resources for each of the plurality of candidate base stations

Represents the percentage of resources used by The utility function is expressed as in the following formula,

Is the mobile station

Set,

Is the uplink transmission rate, and

Is a mobile station among resources for each of the plurality of candidate base stations

Uplink transmission system indicating a ratio of resources used by the.

Images