KR20090000955A - Appratus and method for power contol in wireless communication terminal - Google Patents

Abstract

A power control apparatus and a method thereof in a wireless communications system are provided to reduce interference reaching a large sized base station from a small sized based station. A duplexer(300) transmits reception signal to a reception modem(310) from an antenna according to time division duplex method. A transmission signal is transmitted from a transmission modem(360) to the antenna. Data is restored from the signal which is provided from the duplexer and delivered to a controller(320). A receive power detector(330) is provided from the reception modem with the signal received from neighboring outdoor base stations. The reception power is measured and provided to the power controller(340). The controller receives transmission data from the high layer.

Description

APPARATUS AND METHOD FOR POWER CONTOL IN WIRELESS COMMUNICATION TERMINAL}

1 is a diagram showing the configuration of a wireless communication system using a small base station according to the present invention;

2 is a diagram illustrating a procedure for controlling power in a small base station of a wireless communication system according to an embodiment of the present invention; and

3 is a block diagram of a small base station in a wireless communication system according to the present invention;

The present invention relates to a small base station (Micro Base Station) capable of self-configurable installed indoors in a wireless communication system, in particular, an apparatus and method for automatically controlling the power of the small base station in the wireless communication system It is about.

The wireless communication system is divided into a plurality of zones (hereinafter, referred to as "cells") having a service area of a certain area in order to overcome the limitation of the service area and the limitation of subscriber capacity. In this case, the wireless communication system operates one cell by installing one macro base station in one cell.

In the wireless communication system, an indoor environment such as a building occurs in a cell provided by a base station. Therefore, when a specific terminal is provided with a service from the base station in the indoor environment, the terminal has a problem that the communication environment is degraded due to the influence of the indoor structure and the medium of the building. For example, even if a particular building experiences a small propagation path loss due to its proximity to the base station, the building's exterior wall material and the wall of the building, the number of radio transmission walls and the propagation loss caused by the structure inside the building may be located within the building. The terminal has a problem that the communication environment with the base station is degraded.

Accordingly, the wireless communication system can provide a superior communication environment to terminals located indoors by installing a small base station indoors. In this case, since the large base station managing the cell and the small base station in the large base station use the same system in the wireless communication system, interference between the base stations may occur.

However, if there is no interference between the large base station and the small base station, the small base station may reduce the load of the large base station to increase the capacity of the entire cell and expand the service area. Therefore, when designing a network using a small base station in the wireless communication system, a method for minimizing the amount of interference on the large base station is required.

Accordingly, an object of the present invention is to provide a power control apparatus and method for reducing interference from a small base station capable of self-configuration of a wireless communication system to a large base station.

Another object of the present invention is to provide a power control apparatus and method capable of having a maximum service area or capacity while reducing interference from a small base station capable of self-configuring a wireless communication system to a large base station.

According to a first aspect of the present invention for achieving the above objects, a power control method in a small base station (Micro BS) capable of self-configurable wireless communication system, is located in the vicinity of the small base station and installed outdoors Checking the information of the at least one large base station (Macro BS), and calculating the first power in consideration of interference to the large base stations and handover with the large base station using the information of the large base stations; Calculating a second power that satisfies a Quality of Service (QoS) of terminals located in the indoor base in which the small base station is installed, the first power, the second power, and the maximum power supported by the small base station. And determining the transmission power in consideration of the minimum power.

According to a second aspect of the present invention, a small base station apparatus capable of self configurability of a wireless communication system includes information on at least one large base station located at the periphery of the small base station and installed outdoors; A control unit for checking an environment variable according to a size of a building to be installed and a distance between a large base station and a quality of service (QoS) of terminals located indoors where the small base station is installed, and a reception for confirming reception power of the large base stations A first power that calculates a first power in consideration of interference to the large base stations and handover with the large base station using the power confirmation unit and the information of the large base stations, and satisfies the QoS of the terminals located indoors; It characterized in that it comprises a power control unit for calculating the two power to control the transmission power.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, a description will be given of a technology for controlling power in a micro base station capable of self confifurable wireless communication system. In other words, a description will be given of a power control technique for supporting the maximum service area and capacity of the small base station while reducing interference of the small base station with the macro base station of the wireless communication system. Here, the large base station is a base station installed outdoors and is referred to as an outdoor base station, and the small base station is called a base station installed indoors.

In the following description, the wireless communication system supports handover between an outdoor base station and an indoor base station, and assumes that a dynamic frequency selection technique ideally operates to avoid interference between indoor base stations.

The wireless communication system may configure a network using an indoor base station as shown in FIG. 1.

1 shows a configuration of a wireless communication system using a small base station according to the present invention.

As illustrated in FIG. 1, an outdoor base station 100 installed outdoors of the wireless communication system manages service of a cell. If there is an indoor environment such as a building in a cell managed by the outdoor base station 100, the wireless communication system installs an indoor base station 110 that provides a service indoors to terminals located indoors. It can support excellent communication environment.

It is assumed that the building where the indoor base station is installed has a radius r in order to control power to have the maximum service area or capacity while reducing the interference of the indoor base station of the wireless communication system configured as described above. do. In addition, the indoor base station is located in the center of the building, it is possible to know the distance of the plurality of outdoor base stations and the effective isotropically radiared power (EIRP). In addition, the indoor base station can measure the received power of the outdoor base stations, the outer wall, the inner wall and the inter-floor loss of the building will be described on the assumption that the same in each direction. In this case, the EIRP indicates the transmission power of the signal actually transmitted through the cable loss and the antenna gain in the base station when the base station transmits a signal.

Hereinafter, an operation method for controlling power to have a maximum service area or capacity while reducing interference from an indoor base station to an outdoor base station of the wireless communication system will be described. In the following description, it is assumed that the indoor base station controls power using two outdoor base station information. However, the indoor base station can control power using one or three or more base station information.

2 shows a procedure for controlling power in a small base station of a wireless communication system according to an embodiment of the present invention.

Referring to FIG. 2, first, the indoor base station checks information of outdoor base stations located in the vicinity in step 201. For example, the indoor base station checks the distance from the outdoor base stations, the MIRP of the outdoor base stations, the received power of the outdoor base stations.

After checking the information of the outdoor base stations, the indoor base station proceeds to step 203 to select two base stations having the best reception power among the outdoor base stations.

Thereafter, the indoor base station calculates a first power considering interference with outdoor base stations using the received power of the selected base stations. At this time, the indoor base station should be able to handover with the outdoor base station while minimizing interference to the outdoor base station. Therefore, the indoor base station must calculate the first power so that the power of the signal transmitted by the indoor base station and the power of the signal transmitted by the outdoor base station are the same on the outer wall of the building so as to allow handover with the outdoor base station. That is, when the power of the signal transmitted by the indoor base station and the power of the signal transmitted by the outdoor base station are identical to each other in the outer wall, the effects of interference may be reduced.

For example, when the indoor base station calculates the first power, the power of the signal received from the outdoor base stations can be represented by a value obtained by removing the multipath loss from the EIRP of the outdoor base stations as shown in Equation 1 below. have.

Here, P _RXi represents the power received from the i-th outdoor base station selected according to the received power, and EIRP _i represents the EIRP of the i-th base station. In addition, A and B represent channel environmental variables, and C represents the sum of the penetration loss caused by the outer wall and the path loss inside the building (indoor cell) when the signal transmitted from the outdoor base station passes through the building.

)은 하기와 같이 산출할 수 있다. The total path loss in Equation 1

) Can be calculated as follows.

The multipath loss of the signal received from the outdoor base station in the indoor base station may be represented by Equation 2 below.

Here, PL _ray represents the multipath loss, the PL _outdoor represents the path loss of the outdoor cell, the PL _penetration represents the penetration loss by the outer wall when the signal transmitted from the outdoor base station passes through the building. Indicates path loss inside a building (indoor cell). In addition, the r represents the radius of the building in the shape of a sphere, d represents the distance between the outdoor base station and the indoor base station, θ represents the horizontal angle between the indoor base station and the outdoor base station, and φ is the indoor base station And the vertical angle with the outdoor base station.

In this case, the outdoor cell path loss may be expressed as Equation 3 below.

Here, A and B represent channel environment variables, and the distance represents a distance between a base station and a node receiving a signal of the base station.

Therefore, when Equation 3 is applied to the outdoor cell path loss of Equation 2, multipath loss from the outdoor base station can be expressed as Equation 4 below.

Here, PL _ray denotes multipath loss, A and B denote channel environmental variables, and C denotes a loss of penetration by the outer wall and the inside of the building (indoor cell) when a signal transmitted from an outdoor base station passes through the building. The sum of the path loss of In addition, the r represents the radius of the building in the shape of a sphere, d represents the distance between the outdoor base station and the indoor base station, θ represents the horizontal angle between the indoor base station and the outdoor base station, and φ is the indoor base station And the vertical angle with the outdoor base station.

In Equation 4, assuming that the distance d between the indoor base station and the outdoor base station is much larger than the radius r of the building (d >> r), the entire base station receives signals from the outdoor base station. The multipath loss can be expressed as Equation 5 below.

Here, PL denotes total path loss, A and B denote channel environment variables, and C denotes the loss of penetration by the outer wall and the inside of the building (indoor cell) when the signal transmitted from the outdoor base station passes through the building. The sum of the path loss of

Since the indoor base station knows the distance from the surrounding outdoor base stations and the EIRP of each outdoor base station, E and E can be determined as shown in Equation 6 below.

Here, P _RXi represents the power received from the i-th outdoor base station selected according to the received power, and EIRP _i represents the EIRP of the i-th base station.

In order to reduce the interference from the indoor base station to the outdoor base station and to enable handover with the outdoor base station, the power of the signal transmitted by the indoor base station and the power of the signal transmitted by the outdoor base station in the outer wall of the building is expressed by Equation 7 below. Should be the same as In this case, the outdoor base station indicates the base station having the largest reception power, but may be similarly applied to any base station around the indoor base station.

Here, the EIRP represents the power of the signal actually transmitted by the outdoor base station through the cable loss, antenna gain, d represents the distance between the outdoor base station and the indoor base station, r is the building of the building where the indoor base station is installed Represents the radius. In addition, P _TX1 represents power transmitted from the indoor base station, and FreespaceLoss represents free space loss other than wall loss indoors.

If Equation 7 is summarized as the transmission power of the indoor base station, it can be expressed as Equation 8 below.

는 상기 옥내 기지국이 설치된 옥내에서의 벽 손실 이외의 자유 공간 손실을 나타낸다.Here, the EIRP represents the power of the signal actually transmitted by the outdoor base station through the cable loss, antenna gain, d represents the distance between the outdoor base station and the indoor base station, r is the building of the building where the indoor base station is installed Represents a radius, and P _TX1 represents power transmitted by the indoor base station. At this time, the

Denotes free space loss other than wall loss in the indoor where the indoor base station is installed.

를 옥내 기지국이 설치되는 건물의 크기와 옥외 기지국과의 거리에 따라 결정되는 margin1으로 대체하면, 상기 옥내 기지국의 제 1 전력은 하기 <수학식 9>와 같이 산출할 수 있다.The indoor base station assumes that the distance d between the indoor base station and the outdoor base station is much larger than the radius r of the building in Equation 8 (d >> r). Also, the

Is replaced with margin1 determined according to the size of the building where the indoor base station is installed and the distance from the outdoor base station, the first power of the indoor base station can be calculated as shown in Equation 9 below.

Here, the P _TX1 represents the power for transmitting the signal in consideration of the interference with the outdoor base station in the indoor base station, the EIRP represents the power of the signal actually transmitted through the cable loss, antenna gain, the outdoor base station, D represents a distance between the outdoor base station and the indoor base station. In addition, the margin1 represents a variable determined according to the size of the building in which the indoor base station is installed and the distance from the outdoor base station. Here, the indoor base station increases the margin1 by a certain amount when the transmission power increase amount is large during the power control process, and decreases the margin1 by a certain amount when the transmission power decrease amount is large. For example, Hata and Walfish-Ikegami models, which are models of outdoor path loss, have continuous values of B to 33 to 42 dB. At this time, assuming that the radius of the building is 10 ~ 50 meters the margin1 has a value in the range of -92 ~ -60.

Since the indoor base station can know the values of A and B + C in Equation 6, the indoor base station can calculate the first power using Equation 9.

After calculating the first power in step 205, the indoor base station proceeds to step 307 to calculate a second power that satisfies the maximum service area or capacity of the indoor base station. That is, the indoor base station should satisfy the carrier to noise ratio (CNR) required by the terminals located indoors as shown in Equation 10 below.

Here, P _TX2 represents the transmission power in consideration of the maximum service area or capacity in the indoor base station, C is the penetration loss by the outer wall when the signal transmitted from the outdoor base station passes through the building and in the building (indoor cell) The sum of the path loss of In addition, the FreespaceLoss represents the free space loss other than the wall loss in the indoor, the CNR _TARGET represents the CNR to satisfy the desired minimum Quality of Service (QoS) of the terminal located indoors, N is from the indoor base station Indicates the noise of the terminal receiving the signal.

Equation 10 is summarized as Equation 11 according to the transmission power P _TX2 considering the maximum service area or capacity in the indoor base station.

는 상기 옥내 기지국이 설치된 옥내에서의 벽 손실 이외의 자유 공간 손실을 나타낸다.Here, P _TX2 represents the transmission power in consideration of the maximum service area or capacity in the indoor base station, C is the penetration loss by the outer wall when the signal transmitted from the outdoor base station passes through the building and in the building (indoor cell) N represents the sum of the path loss, and N represents the noise of the terminal receiving the signal from the indoor base station. In addition, the CNR _TARGET represents a CNR for satisfying a desired minimum Quality of Service (QoS) of a terminal located indoors. At this time, the

Denotes free space loss other than wall loss in the indoor where the indoor base station is installed.

를 옥내 기지국이 설치되는 건물의 크기와 옥외 기지국과의 거리에 따라 결정되는 margin2로 대체하면, 상기 옥내 기지국의 제 2 전력은 하기 <수학식 12>와 같이 산출할 수 있다.The indoor base station can know the noise of the terminal in the equation (11),

Is replaced with margin2 determined according to the size of the building where the indoor base station is installed and the distance from the outdoor base station, the second power of the indoor base station can be calculated as shown in Equation 12 below.

Here, the P _TX2 represents the transmission power in consideration of the maximum service area or capacity in the indoor base station, the CNR _TARGET represents the CNR to satisfy the desired minimum quality of service (QoS) of the terminal located indoors, N represents the noise of the terminal receiving the signal from the indoor base station. In addition, the margin2 represents a variable determined according to the size of the building in which the indoor base station is installed and the distance from the outdoor base station. Here, the indoor base station increases the margin2 by a certain amount when the amount of increase in transmission power increases during the power control process, and decreases the margin2 by a certain amount when the amount of decrease in the transmission power increases. For example, Hata and Walfish-Ikegami models, which are models of outdoor path loss, have continuous values of B to 33 to 42 dB. At this time, assuming that the radius of the building is 10 ~ 50 meters the margin2 has a value in the range of -50 ~ -27.

Since the indoor base station knows the values of A and B + C in Equation 6, the indoor base station may calculate the second power using Equation 12.

After calculating the second power in step 207, the indoor base station proceeds to step 209 to determine the transmission power for the maximum service area or capacity of the indoor base station while reducing the interference to the outdoor base station. At this time, the indoor base station determines the power that satisfies Equation (13) as the transmission power.

Here, P _TX represents the transmit power of the indoor base station, P _MAX represents the maximum transmittable power of the indoor base station, and P _min represents the minimum transmittable power of the indoor base station. In addition, P _TX1 represents power for reducing interference effects to the outdoor base station, and P _TX2 represents power for maximum service area or capacity of the indoor base station.

The indoor base station selects a small power by comparing the largest power and the maximum power (P _MAX ) of the first power and the second power as shown in Equation (13). Thereafter, the indoor base station compares the selected power and the minimum power (P _min ) to determine a large power as the transmission power.

The indoor base station then terminates this algorithm.

The following description describes the block configuration of the indoor base station for automatically controlling power as described above.

3 is a block diagram of an indoor base station in a wireless communication system according to the present invention. The following description will be given by taking an indoor base station using a time division duplex scheme as an example, but an indoor base station of another communication scheme may control the same power.

As illustrated in FIG. 3, the indoor base station includes a duplexer 300, a reception modem 310, a control unit 320, a reception power meter 330, a power controller 340, a transmission modem 350, and an outdoor base station. It is configured to include an information confirmation unit 350.

First, the duplexer 300 transmits a reception signal (downlink signal) from the antenna to the reception modem 310 and transmits a transmission signal (uplink signal) from the transmission modem 360 according to a time division duplex scheme. Transfer to the antenna.

The reception modem 310 includes an RF reception block, a demodulation block, a channel decoding block, etc., and restores data from the signal provided from the duplexer 300 and transmits the data to the control unit 320. Here, the RF reception block includes a filter and an RF preprocessor, and the demodulation block includes an FFT operator for extracting data contained in each subcarrier, and the channel decoding block includes a demodulator and a deinterleaver. ) And a channel decoder.

The reception power meter 330 receives a signal received from surrounding outdoor base stations from the reception modem 310 and measures the reception power using the signals and provides the signal to the power controller 340. In this case, the received power is used to calculate the first power as shown in Equation 1 above.

The control unit 320 receives transmission data from an upper layer, processes the transmission data according to a connection method with the transmission modem 350, and transmits the transmission data to the transmission modem 350. In addition, the control unit 320 receives the received data from the reception modem 310, and processes the received data in accordance with the connection method with the upper layer, and transmits the received data to the upper layer. Further, the control unit 320 confirms the information of the outdoor base stations located around the indoor base station through the outdoor base station information verification unit 360. At this time, the control unit 320 determines the margin 1 and margin 2 values of Equations 9 and 12 according to the size of the building where the indoor base station is installed, the distance from the outdoor base station, and the CNR according to the QoS of the indoor users. Determine and provide to the power controller 340. Here, the controller 320 may directly calculate the margin1 and margin2 values or may receive and confirm the margin1 and margin2 values provided from an upper layer.

The power controller 340 uses the outdoor base station information provided from the control unit 320, the CNR according to the QoS of indoor users, and the received power of the outdoor base stations provided from the reception power meter 330. Calculate. For example, although the power controller 340 is not shown, a first power calculation for calculating a first power for reducing interference to an outdoor base station as shown in Equation 9 using the received power of the outdoor base stations. It comprises a group.

In addition, although not shown, the power controller 340 calculates a second power calculator that calculates a second power for a maximum service area or capacity using Equation 12 according to QoS of the indoor users. It is configured to include.

In addition, although not shown, the power controller 340 is configured to include a power determiner for determining the transmission power by applying the first power and the second power to the equation (13).

The transmission modem 350 includes a channel code block, a modulation block, an RF transmission block, and the like, and converts the data (burst data) from the control unit 350 into a form for transmission of a radio section to the duplexer 300. To pass). In this case, the transmission modem 350 amplifies and transmits the signal using the transmission power determined by the power controller 340.

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

As described above, by controlling the transmission power to reduce the interference from the small base station capable of self-configuring the wireless communication system to the base station installed outdoors and to maximize the service area or capacity, the interference to the base station installed outdoors is reduced There is an advantage that can increase the service efficiency of the installed base station and the service efficiency indoors that the small base station provides a service.

Claims (19)

In the power control method in a small base station (Micro BS) capable of Self Configurable of a wireless communication system, Checking information of at least one large BS located in the periphery of the small BS and installed outdoors; Calculating first power in consideration of interference on the large base stations and handover with the large base station using the information of the large base stations; Calculating a second power that satisfies a Quality of Service (QoS) of terminals located indoors where the small base station is installed; And determining transmission power in consideration of the first power and the second power, and the maximum power and the minimum power supported by the small base station. The method of claim 1, And the information of the large base stations includes at least one of a distance from the large base stations, an effective isotropically radiated power (ERIP) of the large base stations, and received power from the large base stations. The method of claim 1, The process of calculating the first power, Checking an environment variable according to the size of the building where the small base station is installed and the distance from the large base station; And calculating the first power such that the transmit power of the small base station and the transmit power of the large base station are the same on the outer wall of the building in consideration of the environmental variable. The method of claim 1, The first power is calculated as in the following equation (14).

Here, the P _TX1 is the power for transmitting a signal in consideration of the interference with the large base station in the small base station, the EIRP is the power of the signal actually transmitted through the cable loss, antenna gain, the d is the The distance between the large base station and the small base station, the margin1 is an environmental variable that is determined according to the size of the building in which the small base station is installed and the distance between the large base station, A, B is an environmental variable for calculating the outdoor path loss, C is the sum of the loss of penetration by the outer wall and the path loss inside the building (indoor cell) as the signal transmitted from the large base station passes through the building. The method of claim 1, The process of calculating the second power, Checking the signal-to-noise ratio according to the environment variable according to the size of the building where the small base station is installed and the distance from the large base station and the QoS of the terminals located indoors; And calculating the second power to satisfy the signal-to-noise ratio in consideration of the environmental variable. The method of claim 1, The second power is calculated using the following equation (15).

Here, the P _TX2 is the transmission power in consideration of the maximum service area or capacity in the small base station, the CNR _TARGET is a signal-to-noise ratio to satisfy the desired minimum QoS of the terminal located indoors, N is the terminal of the indoor location Noise, the margin2 is an environmental variable determined according to the size of the building in which the small base station is installed and the distance from the large base station, A and B are environmental variables for calculating an outdoor path loss, and C is transmitted from the large base station When a given signal passes through a building, it represents the sum of the loss of penetration by the outer wall and the path loss inside the building (indoor cells). The method of claim 1, The process of calculating the transmission power, Selecting a small power by comparing the larger power of the first power and the second power with the maximum power supported by the small base station; And comparing the small power with the minimum power supported by the small base station to calculate the large power as the transmission power. The method of claim 1, And controlling the power of the transmission signal by using the determined power and transmitting the power to the outside through an antenna. A small base station apparatus capable of self configurable wireless communication system, Located in the periphery of the small base station and located in the indoor environment in which the environment information according to the information of at least one large base station installed in the outdoors, the size of the building in which the small base station is installed and the distance to the large base station A control unit for checking the quality of service (QoS) of the terminals; A reception power checking unit for checking reception power of the large base stations; The first power is calculated in consideration of the interference to the large base stations and the handover with the large base station by using the information of the large base stations, and the second power that satisfies the QoS of the terminals located indoors is calculated. And a power control unit for controlling the transmission power. The method of claim 9, The controller checks information of the large base stations including at least one of a distance from the large base stations, an effective isotropically radiated power (ERIP) of the large base stations, and the received power from the large base stations. Device. The method of claim 9, The control unit, characterized in that for checking the environment variable determined according to the distance between the large base station and the size of the building in which the small base station provided from the upper layer. The method of claim 9, The controller may be configured to calculate an environment variable according to the size of the building where the small base station is installed and the distance between the large base station. The method of claim 9, The power control unit, A first power calculator configured to calculate first power in consideration of interference to the large base stations and handover with the large base stations by using information of the large base stations and an environment variable; A second power calculator configured to calculate second power that satisfies QoS of terminals located indoors where the small base station is installed using the environment variable; And a power determiner configured to determine a transmission power in consideration of the first power, the second power, and the maximum power and the minimum power supported by the small base station. The method of claim 13, The first power calculator, And calculating the first power using the information of the outdoor base stations and an environment variable so that the transmission power of the small base station and the transmission power of the large base station are the same on the outer wall of the building where the small base station is installed. The method of claim 13, And the first power calculator calculates a first power by using Equation 16 below.

Here, the P _TX1 is the power for transmitting a signal in consideration of the interference with the large base station in the small base station, the EIRP is the power of the signal actually transmitted through the cable loss, antenna gain, the d is the The distance between the large base station and the small base station, the margin1 is an environmental variable that is determined according to the size of the building in which the small base station is installed and the distance between the outdoor base station, A, B is an environmental variable for calculating the outdoor path loss, C represents the sum of the penetration loss by the outer wall and the path loss inside the building (indoor cell) as the signal transmitted from the large base station passes through the building. The method of claim 13, The second power calculator, And calculating the second power to satisfy a signal-to-noise ratio according to QoS of terminals located indoors where the small base station is installed using the environment variable. The method of claim 13, And the second power calculator calculates the second power using Equation 17 below.

Here, the P _TX2 is the transmission power in consideration of the maximum service area or capacity in the small base station, the CNR _TARGET is a signal-to-noise ratio to satisfy the desired minimum QoS of the terminal located indoors, N is the terminal of the indoor location Noise, the margin2 is an environmental variable determined according to the size of the building in which the small base station is installed and the distance from the large base station, A and B are environmental variables for calculating an outdoor path loss, and C is transmitted from the large base station When a given signal passes through a building, it represents the sum of the loss of penetration by the outer wall and the path loss inside the building (indoor cells). The method of claim 13, The power determiner, Small power is selected by comparing the larger power among the first power and the second power with the maximum power supported by the small base station, and the larger power is transmitted by comparing the selected small power with the minimum power supported by the small base station. The device, characterized in that for calculating. The method of claim 9, And a transmitter for adjusting and transmitting power of a transmission signal according to the control of the power controller.

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