KR20110078298A - Method for changing assignment of carrier frequence band or segment and for managing tx power of the femto ap - Google Patents

Abstract

PURPOSE: A carrier frequency band or a segment allocation exchanging method and a transmission power of a femto type base station management method are provided to selectively control the transmission power of around femto type base stations by exchanging a carrier frequency band or a segment allocation. CONSTITUTION: One of the femto type base station decides whether a necessity of a segment allocation changing or the carrier frequency band that communicates one or more terminals that is based on controlled transmission power size and a signal connection data(316). In case the carrier frequency band or segment allocation need to be changed, the one of the femto type base station transmits a carrier frequency band change request message or a segment allocation alteration require-message to an ACS(Auto Configuration Server)(318,320).

Description

How to change the allocation of carrier frequency bands or segments and how to manage the transmit power of a femto base station {METHOD FOR CHANGING ASSIGNMENT OF CARRIER FREQUENCE BAND OR SEGMENT AND FOR MANAGING TX POWER OF THE FEMTO AP}

The present invention relates to a femto-type base station, and more particularly, to a method for changing allocation of a carrier frequency band or segment used by a femto-type base station and a method for selectively managing transmission power of the femto-type base station.

Recently, due to the rapid development of communication, computer network, and semiconductor technology, various services using wireless communication networks are not only provided, but the demands of consumers are increasing day by day, and the global mobile communication technology is exploding. to be. With the development of mobile communication, users' use forms and demands are also diversified, and they want to communicate without being restricted by time and space. In response to such demands, femto-type base stations are used to compensate for the quality of mobile communication services by installing in areas or shadowed areas where radio waves of macro cells are degraded, such as homes or buildings.

Such a femto-type base station should provide mobile communication services by minimizing signal interference among multiple users. Hereinafter, the operation of the wireless communication system utilizing the conventional femto-type base station will be briefly described. After booting, the femto-type base station receives configuration information from the ACS (Auto Configuration Server) in charge of configuration information and state management of the femto-type base station and applies it to the femto-type base station. At this time, the femto-type base station receives the configuration information from the ACS and provides a service to the terminal of the user at a predetermined transmit power (Tx Power), periodically associated with the uplink / downlink signal for the terminal measured in the femto-type base station Measurement data (eg, including CINR values) is used to dynamically adjust the transmit power. The terminal may measure the signal and transfer the data to the corresponding femto type base station. In addition, the femto-type base station informs the ACS of the adjusted transmission power so that the information on the femto-type base station can be managed consistently.

However, if the transmission power in the femto-type base station is maintained at a predetermined maximum while exceeding a certain threshold that may interfere with other terminals, it will adversely affect the service of other users.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problems of the prior art, for a femto-type base station for which a transmission power is continuously maintained at a predetermined maximum while exceeding a predetermined threshold that may interfere with another terminal, the carrier frequency band or segment To change the allocation or to selectively control the transmission power of the surrounding femto-type base station to provide a mobile communication service to minimize the interference of the signal to the user.

According to an embodiment of the present invention, a method of assigning and changing a carrier frequency band or segment is provided. A wireless communication system comprising at least one terminal, at least one femto-type base station for judging the at least one terminal, and an auto configuration server (ACS) in communication with the at least one femto-type base station-the at least one femto-type base station The first carrier frequency band of the plurality of carrier frequency bands available for communication with the at least one terminal, each of the plurality of carrier frequency bands comprises a plurality of segments, wherein the at least one femto-type base station And using all segments of the first carrier frequency band or only a specific segment to communicate with the at least one terminal, wherein any one of the at least one femto-type base station is connected to the at least one terminal. The carrier frequency band or segment that communicates How to change the assignment includes the steps of said any one of a femto base station type provided with at least one terminal and a signal-related data measurements and periodically measures the signal-specific data that is used for communication; Controlling, by the one femto-type base station, the amount of transmission power to the at least one terminal based on the signal related data measurement value; Determining, by the femto-type base station, whether there is a need to change a carrier frequency band or segment communicating with the at least one terminal based on the signal related data and the magnitude of the controlled transmit power; And when it is determined that there is a need to change the allocation of the carrier frequency band or the segment in the determining step, the one femto-type base station transmitting a carrier frequency band change request message or a segment allocation change request message to the ACS. can do.

In one embodiment, the signal related data may include a carrier to interference and noise ratio (CINR) value.

In an embodiment, the determining may include: determining whether the signal related data measurement value exceeds a predetermined threshold; Counting the number of times the magnitude of the controlled transmission power corresponds to a predetermined maximum transmission power when it is determined that the signal related data measurement value exceeds a predetermined threshold value; Determining whether the counted number is a predetermined number or more; And when it is determined that the counted number is greater than or equal to a predetermined number, determining that the carrier frequency band or segment needs to be changed.

In one embodiment, the sending of the carrier frequency band or segment allocation change request message to the ACS by any one femto-type base station, whether any one femto-type base station uses a specific segment or all segments Judging; When it is determined that any one femto-type base station uses a specific segment, the one femto-type base station transmitting a segment allocation change request message to the ACS; And when it is determined that any one femto-type base station uses all segments, the one femto-type base station may transmit a carrier frequency band allocation change request message to the ACS.

In one embodiment, the method of reassigning a carrier frequency band or segment may be configured by the one femto-type base station to instruct a method of reassigning the carrier frequency band or segment by one of the femto-type base stations from the ACS. Receiving a carrier frequency band or segment allocation change response message; And assigning and changing a carrier frequency band or segment used by the femto-type base station when communicating with the at least one terminal based on the carrier frequency band or segment allocation change response message. .

In one embodiment, the method of changing the allocation of the carrier frequency band or segment by any one femto-type base station is determined by a radio resource allocation change determination performed by the ACS, and the radio resource allocation change determination is performed by the ACS. When a carrier frequency band allocation change request message is received, in a femto-type base station other than the one femto-type base station in which all of the plurality of carrier frequency bands available to one of the femto-type base stations communicate with the ACS. Determining whether it is being used; In response to determining that all of the usable plurality of carrier frequency bands are used in the femto type base station other than the one femto type base station in communication with the ACS, the carrier having the smallest frequency used among the plurality of carrier frequency bands. Determining a frequency as a carrier frequency for use by any one of the femto-type base stations; And any of the plurality of carrier frequency bands that are not in use, in response to determining that all of the usable plurality of carrier frequency bands are not used in any femto-type base station other than the one femto-type base station in communication with the ACS. The frequency band may include determining a carrier frequency band to be used by any one femto-type base station.

In an embodiment, the radio resource allocation change determination may include: counting a number of times the ACS receives the segment allocation change request message when the ACS receives the segment allocation change request message; If the counted number is greater than or equal to a predetermined number, following the procedure when the ACS receives the carrier frequency band allocation change request message; If the counted number is less than a predetermined number, determining whether all of the plurality of segments that can be used by one of the femto-type base stations are used by another femto-type base station communicating with the ACS; Determining that any one of the unused segments is a segment to be used by any one of the femto-type base stations when it is determined that there is a segment not currently used by another femto-type base station communicating with the ACS; If it is determined that the other femto-type base station communicating with the ACS is currently using all segments, the step of determining that the segment having the smallest frequency used among the plurality of segments is the segment to be used by the one femto-type base station. It may further include.

According to an embodiment of the present invention, a method for managing transmission power of a femto-type base station may be provided. A wireless communication system comprising at least one terminal, at least one femto-type base station overcoming the at least one terminal, and an ACS in communication with the at least one femto-type base station, wherein the at least one femto-type base station is the at least one; Uses a first carrier frequency band of the plurality of carrier frequency bands available for communicating with the terminal, and the at least one femto-type base station also uses all segments of the first carrier frequency band for communicating with the at least one terminal; Or using only a specific segment, the method for managing transmission power of the at least one femto-type base station includes periodically measuring signal related data used when the first femto-type base station communicates with the at least one terminal. Providing a signal related data measurement; Controlling, by the first femto-type base station, a magnitude of transmit power to the at least one terminal based on the signal related data measurement value; Determining, by the first femto-type base station, whether the first femto-type base station needs to change the carrier frequency band or segment in which the first femto-type base station communicates with the terminal; In the determining, when it is determined that there is a need to change a carrier frequency band or segment, the first femto-type base station transmitting a carrier frequency band or segment allocation change request message to the ACS; And in response to the ACS receiving the carrier frequency band or segment allocation change request message, a femto-type base station to use the maximum transmit power of the at least one femto-type base station, and a femto-type base station to turn off or reduce the transmit power. It may include the step of selecting.

In one embodiment, the at least one femto-type base station further comprises the step of transmitting its location information to the ACS, wherein the selecting step is to select based on at least one of the location information and the signal-related data. Can be.

The at least one femto-type base station may further include receiving location information of the at least one mobile terminal from the at least one mobile terminal and transmitting the location information to the ACS. May be selected based on at least one of the location information of the at least one femto-type base station, the location information of the at least one mobile terminal, and the signal related data.

According to an embodiment of the present invention, interference with other terminals in the service area of a specific femto-type base station may be reduced by changing a carrier frequency band allocation or a segment allocation. In addition, according to another embodiment of the present invention, it is possible to reduce the interference between the femto-type base station through the transmission power control of another femto-type base station adjacent to a particular femto-type base station.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present invention, when the same numbers indicate the components described in the drawings and the detailed description, generally refer to the same components.

1 is a schematic diagram of an exemplary communications network environment 100 in which the present invention may be practiced. As shown in FIG. 1, the communication network environment 100 may include femto-type base stations 110a and 110b (referred to as 110 when referring to general matters for femto-type base stations) and ACS (Auto Configuration Server) 120. Can be. The femto-type base station 110a and 110b may provide a communication service to the terminal. Although FIG. 1 illustrates that the communication network environment 100 includes two femto-type base stations 110a and 110b and one ACS 130, this is for ease of explanation and the number and arrangement of actual base stations and terminals are similar thereto. Note that this may vary.

The communication network environment 100 is, for example, Code Division Multiple Access (CDMA), Wideband Code Division Multiple Access (WCDMA), Global System for Mobile communications (GSM), Universal Mobile Telecommunications System (UMTS), Worldwide Interoperability for Microwave Access ), Including HSDPA (High Speed Downlink Packet Access) and Long Term Evolution (LTE), including both 2G, 3G, 3.5G and 4G to be developed, and next generation mobile networks, and future mobile networks. have.

In one embodiment of the present invention, the femto-type base station 110, based on the measurement data for the uplink / downlink signal, determines that its transmission power is maintained at the maximum that can interfere with other terminals, Accordingly, the carrier frequency band or segment allocation change request message may be transmitted to the ACS 120, and the ACS 120 may make a predetermined determination on the carrier frequency band or segment allocation change request to the ACS 120. May be assigned to change the carrier frequency band or segment. In one embodiment, the ACS 120 may respond to turn off the power of the specific femto-type base station or to reduce the transmission power according to the allocation change request of the carrier frequency band or segment.

The femto-type base station may communicate with the terminal using a specific carrier frequency band of a plurality of available carrier frequency bands. In addition, a femto-type base station physically divides a radio resource into several segments (one segment is a kind of radio resource division unit consisting of several subchannels) within a frequency band having a specific carrier frequency band. Only specific segments may be used to communicate with the terminal (PUSC; Partial Use of Sub-Carriers), or may be communicated with the terminal using all frequency bands (ie, all segments) of one specific carrier frequency (Frequency). Assignment). Hereinafter, in the present specification, when the femto-type base station communicates with the terminal using only a specific segment of one specific carrier frequency band, it is referred to as "communication using a specific segment". When communicating with the terminal using the frequency band (that is, all segments) will be described as "communication using all segments".

In addition, in the present invention, "assigning and changing the carrier frequency band" means that the specific carrier frequency band used by the femto-type base station in communication with the terminal is changed to one of a plurality of available carrier frequency bands. In the present invention, "segment allocation change" means that the femto-type base station changes the allocation to any one of a plurality of segments that can be used within a frequency band having a specific carrier frequency band when communicating with the terminal. Meaning, it will be apparent to those skilled in the art, detailed description thereof will be omitted.

In one embodiment of the present invention, by changing the allocation of the carrier frequency band, a specific femto-type base station can reduce interference by using a carrier frequency band different from the surrounding femto-type base station, and in another embodiment of the present invention, the segment is allocated. By changing, a particular femto-type base station can reduce the interference by using a segment in a specific carrier frequency band different from the surrounding femto-type base station.

2 is a block diagram of a femto-type base station 110 and the ACS 120 according to an embodiment of the present invention. It is noted that the components shown in FIG. 2 are exemplary, and each component may be integrated, separated, or omitted according to a design specification, and the connection relationship of each component may also be changed.

As shown in FIG. 2, the femto-type base station 110 may include a communication unit 111 capable of transmitting and receiving data with the ACS 120. The communication unit 111 may report various information from the ACS 120, or may transmit a carrier frequency band or a segment allocation change request message to the ACS 120.

As shown in FIG. 2, the femto-type base station 110 may further include a signal data measuring unit 112. The signal data measuring unit 112 may periodically measure data related to uplink and downlink signals used in communication with the terminal. In one embodiment, the signal data measuring unit 112 may receive data related to uplink and downlink signals from a terminal in the jurisdiction of the femto-type base station 110. For example, the data may include a carrier to interference and noise ratio (CINR) value. Data related to the signal obtained by the signal data measuring unit 112 may be transmitted to the ACS 120 through the communication unit 111.

As shown in FIG. 2, the femto-type base station 110 may further include a transmission power controller 113. The transmission power control unit 113 may control the transmission power (Tx power) used when the femto-type base station 110 communicates with the terminal in the jurisdiction. In one embodiment, if the transmission power control unit 113 determines that there is a large amount of interference in the signal, the transmission power controller 113 may increase the size of the transmission power. The transmission power control unit 113 may control the magnitude of the transmission power based on the data measured by the signal data measuring unit 112. In one embodiment, the transmission power control unit 113 may predefine a range that can be controlled. In one embodiment, the transmission power control unit 113 may set the transmission power to a maximum value when there is interference in the signal to exceed a predetermined threshold value in the data measured by the signal data measuring unit 112.

As shown in FIG. 2, the femto-type base station 110 may further include an allocation change determiner 114. The allocation change decision unit 114 may determine whether the femto-type base station 110 should change the allocation of the carrier frequency band of the signal communicating with the terminal in its jurisdiction. In an embodiment, the allocation change decision unit 114 may determine whether the femto-type base station 110 should change the allocation of the segment of the signal communicating with the terminal in its jurisdiction.

In an embodiment, the allocation change determination unit 114 may check whether the data periodically measured by the signal data measuring unit 112 deviates from a predetermined threshold. Here, “out of threshold” may mean a criterion for determining that the signal starts to be interfered with. For example, when the CINR falls below a predetermined threshold, it may be determined that the interference received by the signal has exceeded a predetermined allowable value.

If the above data is out of a predetermined threshold, it is checked whether the size of the transmission power dynamically controlled by the transmission power control unit 113 corresponds to the predetermined maximum transmission power, and if the maximum transmission power corresponds, the count is increased by one. Can be. In one embodiment, the count corresponding to the maximum transmission power must be continuously maintained to increment the count by one, and in another embodiment, the count may be increased by one.

When the sum of the counts is n, the allocation change decision unit 114 may determine whether the corresponding femto-type base station 110 is using a specific segment or all the segments to communicate with the terminal. Here, n is a natural number of 2 or more, and in one embodiment of the present invention, n is 4. If only one specific segment is used, the allocation change decision unit 114 may transmit a segment allocation change request message to the ACS 120 via the communication unit 111. If all segments are used, the allocation change decision unit 114 may transmit a carrier frequency band allocation change request message to the ACS 120 via the communication unit 111.

As shown in FIG. 2, the femto-type base station 110 may further include a location determiner 115. In an embodiment of the present invention, the location determiner 115 may include a femto-type base station location determiner and / or a terminal location determiner.

In one embodiment of the present invention, the femto-type base station position determination unit may obtain the position information of the femto-type base station 110. The femto-type base station location determination unit may obtain the location information of the femto-type base station 110 by using a Global Positioning System (GPS) technology, and may obtain its own location by using a location acquisition technology known in other industries. The detailed description is omitted. In an embodiment of the present invention, the terminal location determiner may receive location information about the terminal from the terminal in the jurisdiction of the femto-type base station 110 to obtain the location information of the terminal. The terminal may periodically transmit its location information to the terminal location determiner of the femto-type base station 110.

In an embodiment, the location determiner 115 may transmit the location information about the femto-type base station 110 obtained from the femto-type base station location determiner and / or the terminal location determiner 110 and / or the terminal of the jurisdiction. Transmit to the ACS 120. In an embodiment, when the femto-type base station 110 is booted, location information may be transmitted to the ACS 120.

As shown in FIG. 2, the ACS 120 may include a communication unit 121 capable of transmitting and receiving data with the femto-type base station 110. The communication unit 121 may receive a carrier frequency band or segment allocation change request message from the femto-type base station 110 or transmit a carrier frequency band or segment allocation message to the femto-type base station 110.

As shown in FIG. 2, the ACS 120 may further include a radio resource allocation changer 122. The radio resource allocation changing unit 122 may function to change the carrier frequency band or segment in response to the carrier frequency band allocation change request or the segment allocation change request of the femto-type base station 110. In one embodiment, the radio resource allocation changing unit 122 may include a carrier frequency band allocation changing unit 122a and a segment allocation changing unit 122b.

The radio resource allocation changing unit 122 may receive a carrier frequency band allocation changing request message or a segment allocation changing request message from the feasto base station 110 determining whether to change the allocation through the communication unit 121. When the radio resource allocation changing unit 122 receives the segment allocation change request message, the radio resource allocation changing unit 122 may store the number of reception. When the radio resource allocation changing unit 122 receives the segment allocation change request message from the same femto-type base station 110 more than m times, the carrier frequency band allocation changing unit 122a is operated. Otherwise, the segment allocation changing unit 122 is operated. 122b may be made to operate. M is a natural number of 2 or more, and in one embodiment of the present invention, n is 2. When the radio resource allocation changing unit 122 receives the carrier frequency band allocation changing request message, the carrier frequency band allocation changing unit 122a may be operated.

In one embodiment, if there is a segment that the femto-type base station 110 is not currently used, the segment allocation changer 122b may apply it to a signal between the femto-type base station 110 and the terminal of the current jurisdiction. If there is no segment currently used by the femto-type base station 110, the segment with the least usage frequency may be applied to the signal between the femto-type base station 110 and the terminal of the current jurisdiction. The segment allocation changing unit 122b may transmit the segment allocation response selected to the femto type base station 110 through the communication unit 121.

In one embodiment, the carrier frequency band allocation changer 122a randomly selects unused carrier frequency bands from a plurality of available carrier frequencies (that is, the entire frequency band pool managed by the ACS 120) to form a femto type. It can be used for communication between the base station 110 and the terminal of the current jurisdiction. If all of a plurality of available carrier frequency bands are used, a carrier frequency band having a low use frequency may be used for communication between the femto-type base station 110 and a terminal of the current jurisdiction. The carrier frequency band allocation changing unit 122a may transmit a carrier frequency band allocation changing response to the femto type base station 110 through the communication unit 121.

As shown in FIG. 2, the ACS 120 may further include a femto-type base station location database 124. The femto-type base station location database 124 may store the location and location information of the femto-type base stations received from the position determiner 115 of the femto-type base station 110.

As shown in FIG. 2, the ACS 120 may further include a femto type base station controller 123. In one embodiment, the femto-type base station control unit 123 is a location stored in the femto-type base station location database 124 when the ACS 120 receives a carrier frequency band or segment allocation change request through the communication unit 121 Based on the information and / or data on the signal received from the signal data measuring unit 112 of the plurality of femto-type base stations 110, the femto-type base station to use the maximum transmission power, and the femto-type to turn off or reduce the transmission power The base station can be selected. In one embodiment of the present invention, a femto-type base station located geographically close to the mobile terminal may be selected as a femto-type base station to use the maximum transmission power, the femto base station located in a distant place to turn off or reduce the transmission power It can be selected as a femto-type base station. In another embodiment of the present invention, a femto base station having a relatively good communication state is selected to use the maximum transmission power based on data about signals received from a plurality of femto base stations, and the communication state is not good. The transmission power of the femto-type base station may be selected to be turned off or reduced. That is, the femto-type base station controller 123 may function to reduce the transmission power of the femto-type base station determined to cause interference to the extent that no interference occurs. In another embodiment of the present invention, the femto-type base station controller 124 checks the area where the cell coverage overlaps based on the relative position information of the femto-type base stations and the average transmission power, and thus transmits some of the femto-type base station The amount of power can be reduced.

In order to explain the operation of the femto-type base station control unit 123 more specifically and intuitively, two femto-type base stations 110a and 110b communicating with the ACS 120 and the overlapping area of the jurisdiction of the two femto-type base stations are duplicated. It is assumed that there is a terminal in the area and the terminal is located closer to the femto-type base station 110a than the femto-type base station 110b, so that the terminal can communicate with the femto-type base station 110a more smoothly. The femto-type base station 110a may transmit a carrier frequency band or segment allocation change request to the ACS 120 (due to an increase in signal interference due to the femto-type base station 110b). In response, the femto-type base station control unit 123 transmits the position information of the femto-type base stations 110a and 110b, the position information of the terminal, and the data about the signal received from the femto-type base stations 110a and 110b (that is, within a signal). If the transmission power of the femto-type base station 110b is lowered or the transmission power is turned off based on the measured value of the interference), the interference between the femto-type base station 110a and the terminal can be significantly reduced. It can be determined that there is no problem with the communication service to the furnace. Accordingly, the femto-type base station controller 123 may increase or change the transmit power of the femto-type base station 110a and reduce the transmit power of the femto-type base station 110a or turn off the power.

3 is a flowchart illustrating in detail a procedure for transmitting a carrier frequency band or segment allocation change request message in a femto-type base station 110 according to an embodiment of the present invention, and FIG. 4 is an ACS according to an embodiment of the present invention. FIG. 5 is a flowchart illustrating in detail a procedure of allocating and changing a carrier frequency band or segment at FIG. 120, and FIG. 5 illustrates a femto-type base station using a maximum transmit power in the ACS 120 according to an embodiment of the present invention. The femto-type base station is a flowchart illustrating a procedure for not using it. It is noted that the steps shown in FIGS. 3 to 5 are exemplary, and each step may be combined, separated or omitted, and the order of the steps may be changed.

3 shows a procedure from the femto-type base station 110 to the carrier frequency band or segment allocation change request message to the ACS 120. First, the femto-type base station 110 may periodically measure data (eg, CINR) related to uplink and downlink signals used in communication with the terminal (step 300). According to the measured signal value, the femto-type base station 110 may dynamically control the magnitude of the transmission power (step 302). In this case, it may be determined whether the signal measurement value deviates from a predetermined threshold (step 304). If the signal measurement does not deviate from the predetermined threshold, then step 300 may be returned (step 306).

If the signal measurement is outside the predetermined threshold, it may be determined whether the magnitude of the controlled transmit power corresponds to the predetermined maximum transmit power (step 308). If it does not correspond to the maximum transmit power may be returned to step 300 (step 310). When the maximum transmission power corresponds to the maximum transmission power, the number of times set as the maximum transmission power may be counted, and it may be determined whether the counted number is greater than or equal to n predetermined times (step 312). If less than n times, it may return to step 300 (step 314). If more than n times, it is possible to determine whether the corresponding femto-type base station uses all segments or a specific segment to communicate with the terminal (step 316). If it is determined that the particular segment is to be used, then a segment allocation change request message can be sent to the ACS 120 (step 318). If it is determined that all segments are used, the carrier frequency band allocation change request message can be sent to the ACS 120 (step 320).

4 illustrates a procedure of allocating a carrier frequency band or a segment in the ACS 120 and transmitting an allocation change response message to the femto-type base station 110. First, a radio resource allocation change request may be received from the femto-type base station 110 (step 400). If the received radio resource allocation change request is a segment allocation change request message, the number of reception is counted. If the segment allocation change request message has been received n or more times, the process may proceed to step 412 (step 402). If the segment allocation change request message is received less than n times, the femto-type base station 110 may determine whether there is a segment that is not currently used in the allocated frequency band by the femto-type base station (step 404). If there is a segment that is not currently used, it may be randomly selected from the segments that are not used and applied to the signal between the femto-type base station 110 and the terminal of the current jurisdiction (step 406). If there is no segment that is not currently used within the allocated frequency band by the femto-type base station 110, the segment with the least usage frequency may be applied to the signal between the femto-type base station 110 and the terminal of the current jurisdiction (step). 408). Thereafter, the ACS 120 may transmit a segment allocation change response message including the segment information selected in step 406 or step 408 to the femto-type base station 110 (step 410).

If the message received from the femto-type base station 110 is a carrier frequency band allocation change request message, it may be determined whether all carrier frequencies belonging to the entire carrier frequency band pool managed by the ACS 120 are used. 412). If all available carrier frequencies (ie, registered in the carrier frequency band pool) are used, it may be determined that the carrier frequency band having a low frequency of use is used for communication between the femto-type base station 110 and the terminal of the current jurisdiction. (Step 414). If there is an unused carrier frequency band among the available carrier frequency bands, one of the unused carrier frequency bands is randomly determined to be used in communication with the femto-type base station 110 and the terminal of the current jurisdiction. May be step 416. The ACS 120 may then transmit a carrier frequency band allocation change response message to the femto-type base station 110 that includes the information in step 414 or step 416 (step 418).

FIG. 5 shows a procedure for selecting a femto-type base station to use the maximum transmission power in the ACS 120 and reducing or turning off transmission power of other femto-type base stations. First, the location of the femto-type base stations with which the ACS 120 communicates and / or the location information of the terminal in the jurisdiction of the femto-type base station and / or data about the signal received from the femto-type base stations (ie, measurement of interference in the signal) Value) can be received from the femto-type base station (step 500). At this time, the location information of the terminal of the femto-type base station jurisdiction can be periodically received from the femto-type base station. ACS 120 may then receive a radio resource allocation change request message from the femto-type base station (step 502). The ACS 120 may then be based on the location of the femto-type base stations and / or the location information of the terminal in the jurisdiction of the femto-type base station and / or data about the signal received from the femto-type base stations (ie, measurement of interference in the signal). In operation 504, a femto-type base station to use the maximum transmit power and a femto-type base station to turn off or reduce the transmit power may be selected. ACS 120 may then send a response message including this information to each femto-type base station (step 506).

Although the foregoing methods have been described through specific embodiments, the foregoing methods may also be embodied as computer readable codes on a computer readable recording medium. Computer-readable recording media include all kinds of recording devices that store data that can be read by a computer system. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, optical data storage devices, and the like, which are also implemented in the form of carrier waves (for example, transmission over the Internet). Include. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion. In addition, functional programs, codes, and code segments for implementing the above-described embodiments can be easily inferred by programmers in the art to which the present invention belongs.

In addition, while the present invention has been described in connection with some embodiments, it is to be understood that various modifications and changes can be made without departing from the spirit and scope of the invention as will be understood by those skilled in the art. You will need to know It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

1 is a schematic diagram of an exemplary communications network environment 100 in which the present invention may be practiced.

2 is a block diagram of a femto-type base station 110 and the ACS 120 according to an embodiment of the present invention.

3 is a flowchart illustrating a procedure of transmitting a carrier frequency band or segment allocation change request message in a femto-type base station according to an embodiment of the present invention.

4 is a flow chart illustrating in detail the procedure of assigning and changing a carrier frequency band or segment in an ACS according to one embodiment of the invention.

5 is a flowchart illustrating a procedure for selecting a femto-type base station to use the maximum transmission power in the ACS and not using other femto-type base stations according to an embodiment of the present invention.

Claims (10)

A wireless communication system comprising at least one terminal, at least one femto-type base station for judging the at least one terminal, and an auto configuration server (ACS) in communication with the at least one femto-type base station-the at least one femto-type base station The first carrier frequency band of the plurality of carrier frequency bands available for communication with the at least one terminal, each of the plurality of carrier frequency bands comprises a plurality of segments, wherein the at least one femto-type base station And using all segments of the first carrier frequency band or only a specific segment to communicate with the at least one terminal, wherein any one of the at least one femto-type base station is connected to the at least one terminal. The carrier frequency band or segment A method of changing sugar, Periodically measuring signal-related data used when the one femto-type base station communicates with the at least one terminal, and providing a signal-related data measurement value; Controlling, by the one femto-type base station, the amount of transmission power to the at least one terminal based on the signal related data measurement value; Determining, by the femto-type base station, whether there is a need to change a carrier frequency band or segment communicating with the at least one terminal based on the signal related data and the magnitude of the controlled transmit power; And If it is determined in the determining step that it is necessary to change the allocation of the carrier frequency band or segment, the femto-type base station transmitting a carrier frequency band change request message or a segment allocation change request message to the ACS; , Way. The method of claim 1, And the signal related data comprises a carrier to interference and noise ratio (CINR) value. The method of claim 1, The determining step, Determining whether the signal related data measurement value exceeds a predetermined threshold; Counting the number of times the magnitude of the controlled transmission power corresponds to a predetermined maximum transmission power when it is determined that the signal related data measurement value exceeds a predetermined threshold value; Determining whether the counted number is a predetermined number or more; And If it is determined that the counted number is greater than or equal to a predetermined number, determining that the carrier frequency band or segment needs to be changed. The method of claim 1, The one femto-type base station transmits a carrier frequency band or segment allocation change request message to the ACS, Determining which one of the femto-type base stations uses a specific segment or all segments; When it is determined that any one femto-type base station uses a specific segment, the one femto-type base station transmitting a segment allocation change request message to the ACS; And If it is determined that any one femto-type base station uses all segments, the one femto-type base station sends a carrier frequency band allocation change request message to the ACS. 5. The method of claim 4, Receiving, by the one femto-type base station, from the ACS, a carrier frequency band or segment allocation change response message indicating how the one femto-type base station allocates and changes the carrier frequency band or segment; And And assigning or changing a carrier frequency band or segment used by the femto-type base station when communicating with the at least one terminal based on the carrier frequency band or segment allocation change response message. The method of claim 5, The method of changing the allocation of the carrier frequency band or segment by any one femto-type base station is determined by a radio resource allocation change determination performed by the ACS, The radio resource allocation change determination When the ACS receives the carrier frequency band allocation change request message, all of a plurality of carrier frequency bands that can be used by any one femto type base station communicate with the ACS. Determining whether the base station is being used; In response to determining that all of the usable plurality of carrier frequency bands are used in the femto type base station other than the one femto type base station in communication with the ACS, the carrier having the smallest frequency used among the plurality of carrier frequency bands. Determining a frequency as a carrier frequency for use by any one of the femto-type base stations; And Any carrier frequency of the plurality of unused carrier frequency bands in response to determining that all of the usable plurality of carrier frequency bands are not used in any femto-type base station other than the one femto-type base station communicating with the ACS. Determining a band in a carrier frequency band for use by any one of the femto-type base stations. Including, method. The method of claim 6, The radio resource allocation change determination, Counting, by the ACS, the number of times of receiving the segment allocation change request message when the segment allocation change request message is received; If the counted number is greater than or equal to a predetermined number, following the procedure when the ACS receives the carrier frequency band allocation change request message; If the counted number is less than a predetermined number, determining whether all of the plurality of segments that can be used by one of the femto-type base stations are used by another femto-type base station communicating with the ACS; Determining that any one of the unused segments is a segment to be used by any one of the femto-type base stations when it is determined that there is a segment not currently used by another femto-type base station communicating with the ACS; If it is determined that the other femto-type base station communicating with the ACS is currently using all segments, the step of determining the segment that the least frequently used among the plurality of segments as the segment to be used by any one femto-type base station Further comprising, the method. A wireless communication system comprising at least one terminal, at least one femto-type base station overcoming the at least one terminal, and an ACS in communication with the at least one femto-type base station, wherein the at least one femto-type base station is the at least one; Uses a first carrier frequency band of the plurality of carrier frequency bands available for communicating with the terminal, and the at least one femto-type base station also uses all segments of the first carrier frequency band for communicating with the at least one terminal; Or using only a specific segment, the method for managing transmit power of the at least one femto-type base station; Periodically measuring signal-related data used when the first femto-type base station communicates with the at least one terminal to provide a signal-related data measurement value; Controlling, by the first femto-type base station, a magnitude of transmit power to the at least one terminal based on the signal related data measurement value; Determining, by the first femto-type base station, whether the first femto-type base station needs to change the carrier frequency band or segment in which the first femto-type base station communicates with the terminal; In the determining, when it is determined that there is a need to change a carrier frequency band or segment, the first femto-type base station transmitting a carrier frequency band or segment allocation change request message to the ACS; And In response to the ACS receiving the carrier frequency band or segment allocation change request message, a femto-type base station to use the maximum transmit power among the at least one femto-type base station, and a femto-type base station to turn off or reduce the transmit power. Method comprising selecting. The method of claim 8, The at least one femto-type base station further transmits its location information to the ACS, Wherein the selecting step is selected based on at least one of the location information and the signal related data. 10. The method of claim 9, The at least one femto-type base station further comprises receiving the location information of the at least one mobile terminal from the at least one mobile terminal, and transmitting to the ACS, The selecting step may be selected based on at least one of the location information of the at least one femto-type base station, the location information of the at least one mobile terminal, and the signal related data.

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