KR20100091326A - Apparatus and method for uplink resource allocating in wireless communication system - Google Patents

Abstract

PURPOSE: An apparatus and a method for allocating an uplink resource in a wireless communication system are provided to make an inter-cell interference size and a reference interference size smaller. CONSTITUTION: A base station determines a set MCS(Modulation and Coding Scheme) level as an MCS level of a corresponding terminal(113). The base station determines a size of burst used for data transmission of terminals(115). The base station determines scheduling priority of the terminals in consideration of the MCS level and the size of burst to be assigned to the determined terminals(117). The base station assigns resources to a terminal with the highest scheduling priority(119).

Description

Device and method for allocating uplink resource in wireless communication system {APPARATUS AND METHOD FOR UPLINK RESOURCE ALLOCATING IN WIRELESS COMMUNICATION SYSTEM}

The present invention relates to an apparatus and method for uplink scheduling in a wireless communication system, and more particularly, to an apparatus and method for performing uplink scheduling in consideration of the effect of interference on a neighbor cell in a wireless communication system.

In a wireless communication system of a circuit (circuit) transmission method, the terminals always transmit data constantly. Accordingly, the base station determines only the data rate for each terminal without performing uplink scheduling. For example, a circuit transmission scheme of a code division multiple access (CDMA) scheme uses a circuit transmission scheme.

When determining the data rates for the terminals, the base station collectively adjusts the data rates in consideration of self cell interference, neighbor cell interference, and Rote (Rise of Thermal) size.

Recently, a wireless communication system uses a packet transmission scheme to transmit a large amount of data at high speed. For example, an orthogonal frequency division multiplexing (OFDM) wireless communication system uses a packet transmission scheme.

When using a packet transmission scheme, the terminal does not always transmit data constantly. Accordingly, the base station determines through which scheduling which terminal to transmit data of what size and informs each terminal.

In the uplink, the base station performs uplink scheduling using a signal to interference and noise ratio (CINR) and headroom of a sounding reference signal (SRS) provided from terminals.

In addition, when the packet method is used, the base station cannot adjust its data rate in the same manner as the circuit transmission method because the base station does not generate self-cell interference and only neighbor cell interference. That is, the base station can not maintain a constant RoT of the neighboring cell by controlling the amount of self-cell interference.

Accordingly, an object of the present invention is to provide an apparatus and method for controlling a rise of thermal (RoT) of adjacent cells in a base station of a wireless communication system not to be increased than a reference RoT.

Another object of the present invention is to provide an apparatus and a method for controlling a terminal providing a service in a base station of a wireless communication system so that an interference magnitude affecting neighbor cells does not increase than a reference interference magnitude.

Still another object of the present invention is to control a terminal providing a service through uplink scheduling considering cell interference magnitudes of neighbor cells in a base station of a wireless communication system so that the interference magnitude affecting neighbor cells does not increase than a reference interference magnitude. To provide an apparatus and method for.

Another object of the present invention is an apparatus and method for uplink scheduling so that a transmission rate is maximized while controlling a terminal providing a service in a base station of a wireless communication system not to increase an interference magnitude affecting neighbor cells than a reference interference magnitude. In providing.

According to a first aspect of the present invention for achieving the objects of the present invention, a method for allocating uplink resources in a base station of a wireless communication system includes the steps of checking the magnitude of the inter-cell interference of at least one neighboring base station; Determining a maximum transmit power for at least one terminal in consideration of the magnitude of inter-cell interference for at least one neighboring base station, and considering the maximum transmit power for the at least one terminal, MCS (Modulation) for each terminal and Coding Scheme) to determine the level of the resources to be allocated to each terminal by comparing the MCS level for each terminal and the amount of uplink resources that can be allocated to the terminal for providing a service Determining a scheduling priority for each terminal in consideration of the MCS level and resource size of each terminal. , With the highest scheduling priority terminal is characterized in that it comprises the step of allocating resources of the determined size.

According to a second aspect of the present invention, an apparatus for allocating uplink resources in a base station of a wireless communication system includes a wired interface for transmitting and receiving a signal through at least one neighboring base station through a wired network, and at least provided through the wired interface. A scheduler for allocating resources to terminals through uplink scheduling considering the magnitude of interference between cells of one neighboring base station, and a transmitting device for transmitting resource allocation information to the terminals.

As described above, the base station of the wireless communication system performs uplink scheduling for UEs using rise of thermal (RoT) information provided from neighboring cells, thereby keeping the inter-cell interference transmitted to the neighboring cell lower than the reference interference. In this case, the service area is kept constant and the average data transfer rate is improved, thereby improving the performance of the overall system.

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. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be made based on the contents throughout the specification.

Hereinafter, the present invention describes a technique for uplink scheduling using intercell interference information provided from neighbor cells in a base station of a wireless communication system.

Base stations of a wireless communication system using a packet transmission scheme inform other base stations of the magnitude of inter-cell interference affected by neighboring cells. For example, a base station is periodically provided with a rise of thermal (RoT) from neighboring base stations. Here, the size of RoT increases as the size of intercell interference increases.

In addition, the UE transmits the path loss information measured by analyzing the downlink signals provided from the serving base station and neighboring base stations to the serving base station.

Accordingly, the base station allocates uplink resources of the terminal through uplink scheduling as shown in FIG. 1 using RoTs and path loss information of neighboring base stations.

1 illustrates a procedure for uplink scheduling in a base station according to an embodiment of the present invention.

Referring to FIG. 1, the base station first checks RoTs of neighbor base stations in step 101. For example, the base station receives and stores RoTs which neighboring base stations periodically transmit through the backhaul. At this time, the base station periodically transmits the RoT measured by the base station to the adjacent base stations through the backhaul.

After checking the RoTs of the neighbor base stations, the base station proceeds to step 103 and calculates the amount of tone interference powers that the neighbor base stations can accept from the terminal providing the service using the RoTs of the neighbor base stations checked in step 101. do. For example, the base station calculates the magnitude of the tone interference power for each neighboring base station using Equation 1 below.

Here, ToneRxPower (m) represents the maximum amount of tone interference power that can be accepted by the mth neighboring base station, ToneRxPower _MIN represents the minimum value of the tone interference powers that can be accepted by neighboring base stations, and ToneRxPower _MAX is Represents the maximum value of the tone interference powers that the neighbor base stations can accept, the RoT _MAX represents the maximum value of the RoTs provided from the neighbor base stations, and the RoT _MIN represents the minimum value of the RoTs provided from the neighbor base stations. RoT (m) represents RoT provided from the mth neighboring base station.

As shown in Equation 1, the base station calculates the magnitude of the tone interference power to change linearly according to RoTs provided from neighboring base stations. In this case, as shown in Equation 1, the maximum tone interference power of the neighboring base station calculated by considering the RoT of the neighboring base station is for limiting the size of the transmission power of the terminal to the neighboring base station. Accordingly, when the RoT of the neighboring base station is small, the base station sets the maximum amount of interference that the terminal affects to the neighboring base station. On the other hand, when the RoT of the neighboring base station is large, the base station may set the RoT of the neighboring base stations to a predetermined level by setting a small amount of the maximum interference that the terminal affects the neighboring base station.

After determining the size of the tone interference power that each neighboring base station can accept in step 103, the base station proceeds to step 105 to calculate the maximum tone transmit power of the terminals using the size of the tone interference power of the neighboring base stations. . For example, the base station calculates tone transmission power for each terminal located in the service area by using Equation 2 below.

The ToneTxPower (n) represents the magnitude of the tone transmission power of the nth terminal, the ToneTxPower (n, m) represents the magnitude of the tone power transferred from the nth terminal to the mth neighboring base station, and the ToneRxPower (m) is The maximum tone interference power that can be accepted by the m-th neighboring base station, m is the neighbor base station index, PathLoss (n, m) is the inverse of the path loss for the n-th terminal and the m-th neighboring base station Indicates. Here, the base station receives PathLoss (n, m) information from the nth terminal.

According to Equation 2, the magnitude of the tone power delivered from the nth terminal to the mth neighbor base station is determined by the maximum tone interference power and the path loss that the mth neighbor base station can accept.

Also, the base station sets the smallest value of the tone powers transmitted by the nth terminal to the adjacent base stations as the maximum tone power available to the nth terminal. In this case, the base station calculates the magnitude of the maximum tone interference power of the neighboring base stations to vary linearly according to RoT provided from neighboring base stations as shown in Equation 1 above. Accordingly, since the maximum tone transmit power of the terminal is limited by the neighbor base station having the largest RoT, the RoTs of the neighbor base stations may not be increased beyond the reference RoT.

After calculating the maximum tone transmission power of the terminals in step 105, the base station proceeds to step 107, the maximum carrier to interference and when the terminal transmits data using the maximum tone transmission power calculated in step 105 Noise Ratio) is calculated. That is, the base station calculates a maximum CINR when the terminals receive data transmitting the maximum tone transmission power. For example, the base station calculates CINR for each terminal using Equation 3 below.

Here, AvailableCINR (n) represents the maximum CINR that the base station can be provided from the n-th terminal, the CINR (SRS) represents the CINR for the sounding signal transmitted by the n-th terminal, the ToneTxPower (n) is The maximum tone transmit power of the n-th terminal calculated using Equation 2 is represented, and SRSToneTxPower (n) represents the magnitude of the tone transmit power of the n-th terminal transmitted sounding signal.

As shown in Equation 3, the base station uses the power of the UEs located in the service area to transmit sounding signals and the CINR of the sounding signals, which is calculated by the UE through Equation 2. Calculates the maximum CINR that can be obtained when transmitting data.

After calculating the maximum CINR of the terminals in step 107, the base station proceeds to step 109 to set the maximum modulation and coding scheme (MCS) level that can be used by the terminals to the MCS level for each terminal to transmit data .

Thereafter, the base station proceeds to step 111 and checks whether each terminal can use the MCS level set in step 109. Accordingly, the base station compares the maximum CINR calculated in step 107 with the CINR according to the MCS level of each terminal set in step 109. Here, the CINR according to the MCS level may be referred to as CINR _MSC .

If there are UEs whose maximum CINR calculated in step 107 is greater than or equal to the CINR according to the MCS level set in step 109, the base station can use the MCS level set in step 109. Judging by it. Accordingly, the base station proceeds to step 113 and determines the MCS level set in step 109 as the MCS level of the terminal.

On the other hand, if there are UEs whose maximum CINR calculated in step 107 is smaller than the CINR according to the MCS level set in step 109, the base station determines that the MSs cannot use the MCS level set in step 109. do. Accordingly, the base station proceeds to step 123 and compares the MCS level set in step 109 with the minimum MCS level that can be used by the corresponding terminals.

If the MCS level set in step 109 is the same as the minimum MCS level, the base station proceeds to step 113 and determines the MCS level set in step 109 as the MCS level of the corresponding terminals.

If the MCS level set in step 109 is different from the minimum MCS level, the base station proceeds to step 125 and decreases the MCS level set in step 109 by one step (MCS = MCS-1). Set to the MCS level to use.

Thereafter, the base station returns to step 111 and checks whether the terminals can use the MCS level set in step 125. Accordingly, the base station compares the maximum CINR calculated in step 107 with the CINR according to the MCS level set in step 125. Thereafter, the base station determines the MCS level of the terminals using the MCS level set in step 125.

After determining the MCS level of the terminals in step 113, the base station proceeds to step 115 to determine the size of the burst to be used by the terminals to transmit data. For example, the base station uses Equation 4 below to determine the size of a burst that each terminal uses to transmit data.

Here, the AvailableSlot (n) represents the size of the burst to be used by the n-th terminal to transmit data, the RemainingSlot represents the size of the remaining uplink resources that can allocate resources from the base station to the terminal, the SupportableSlot (n ) Represents the magnitude of the burst that can be transmitted when the nth terminal uses the MCS level of the terminal determined in step 113, the TotalTxPower _MAX (n) represents the maximum transmit power of the nth terminal, the ToneperSlot is in the slot It represents the number of tones included, and the ReqiredToneTxPower _MCS (n) represents the transmit power required for the nth terminal to transmit one tone.

According to Equation 4, the base station compares the remaining uplink resources that can be allocated to the terminals with the magnitude of the burst that can be transmitted when the terminals use the MCS level determined in step 113, and then assigns a small value to the terminals. Assign.

After determining the size of the burst to be allocated to the terminals, the base station proceeds to step 117 to schedule the terminals in consideration of the MCS level of the terminals determined in step 113 and the size of the burst to be allocated to the terminals determined in step 115. Determine your priorities. For example, the base station determines scheduling priorities of the terminals using Equation 5 below. Here, the scheduling priority indicates an order in which the base station allocates resources through uplink scheduling.

Here, Priority (n) represents the scheduling priority of the n-th terminal, the MPR (MCS (n)) represents the MCS level of the n-th terminal determined in step 113, the AvailableSlot (n) is the 115 step Represents the size of the burst to be allocated to the n-th terminal determined by, where R _t represents the average data rate of the n-th terminal, and v represents a fairness factor. Here, v adjusts the degree to which the average data rate of the nth terminal is broadcasted in calculating the PF scheduling priority.

)과 평균 데이터 전송률(

)의 차이를 이용하여 단말의 스케줄링 우선순위를 결정한다. 이에 따라, 인접 기지국으로 큰 간섭의 영향을 미치는 단말은 최대 톤 전송 전력의 제한으로 인해 MCS가 낮아지게 되어 낮은 평균 데이터 전송률을 보장받을 수 있다. 한편, 인접 기지국으로 작은 간섭의 영향을 미치는 단말은 높은 톤 전송 전력의 제한으로 인해 MCS가 커지고 높은 스케줄링 우선순위를 가질 수 있다.According to Equation 5, the base station determines the maximum data rate of the terminal (

) And average data rate (

The scheduling priority of the terminal is determined using the difference of). Accordingly, the terminal having a large interference effect on the neighboring base station may have a low MCS due to the limitation of the maximum tone transmission power, thereby ensuring a low average data rate. On the other hand, the terminal having a small interference effect to the neighboring base station may have a high MCS and high scheduling priority due to the limitation of the high tone transmission power.

After the scheduling priority of the terminals is determined in step 117, the base station allocates resources to the terminal with the highest scheduling priority in step 119. In this case, the base station allocates the burst having the size determined in step 115 to the terminal having the highest scheduling priority.

In step 121, the base station determines whether uplink resources that can be allocated to other terminals remain.

If the uplink resources that can be allocated to the other terminals remain, the base station returns to step 115 and determines the size of the burst that the terminals use to transmit data. That is, since the size of the remaining uplink resource (RemainingSlot) of Equation 4 is changed by allocating the resource to the terminal having the highest priority in step 119, the base station returns to step 115.

On the other hand, when there is no uplink resource that can be allocated to other terminals, the base station terminates the present algorithm. In this case, the base station transmits resource allocation information to the terminals to which the resource is allocated in step 119. Here, the resource allocation information includes information such as the size of the burst allocated to the terminal, the MCS level and the tone transmission power.

In the above-described embodiment, the base station calculates the magnitude of the maximum tone interference power of neighboring base stations so as to vary linearly according to RoT provided from neighboring base stations as shown in Equation 1 above.

In another embodiment, the base station may set the maximum tone interference power of neighboring base stations as shown in Equation 6 below.

Here, ToneRxPower (m) represents the maximum tone interference power that can be accepted by the m-th neighboring base station, Upstep_ToneRxPower represents a setting value for increasing the maximum tone interference power, and Downstep_ToneRxPower represents the maximum tone interference power. The RoT (m) represents a RoT received from an mth neighboring base station, and the RoT _Th represents a RoT reference value.

As shown in Equation 6, the base station periodically sets the maximum tone interference power so that RoTs of neighboring base stations do not exceed a reference RoT (RoT _Th ).

In another embodiment, the base station may set the maximum tone interference power of the neighbor base stations using a table including the maximum tone interference power information according to RoT of the neighbor base station.

In addition, in the above-described embodiment, the base station sets the smallest value of the tone powers transmitted by the nth terminal to the adjacent base stations as the maximum tone power available to the nth terminal using Equation (2). .

In another embodiment, the base station may set the average of the magnitudes of the tone powers transmitted by the nth terminal to the neighbor base stations as the maximum tone power available to the nth terminal by using Equation 7 below.

The ToneTxPower (n) represents the magnitude of the tone transmission power of the nth terminal, the ToneTxPower (n, m) represents the magnitude of the tone power transferred from the nth terminal to the mth neighboring base station, and the ToneRxPower (m) is The maximum tone interference power that can be accepted by the m-th neighboring base station, m is the neighbor base station index, PathLoss (n, m) is the inverse of the path loss for the n-th terminal and the m-th neighboring base station Indicates. Here, the base station receives PathLoss (n, m) information from the nth terminal.

In addition, in the above-described embodiment, the base station determines the scheduling priority of the n-th terminal by using Equation (5).

In another embodiment, the base station may determine the scheduling priority of the n-th terminal using Equation 8 below.

Here, Priority (n) represents the scheduling priority of the n-th terminal, the R _h represents the amount of resources available when using the reference MCS level, the MCS _old is a terminal determined using the normalized headroom L (MCS _old ) denotes a variable for calculating a data rate of a terminal when using R _h and MCS _old , R _t denotes an average data rate of an nth terminal, and MCS _new denotes the MCS of the n-th terminal determined in step 113, T (MCS _new ) represents a variable for calculating the data rate of the terminal when using the R _t and MCS _new , v represents a fairness factor (fairness factor) . Here, R _h can be calculated by modifying the headroom of the reference MCS using the headroom provided from the terminal. In addition, v adjusts the degree to which the average data rate of the nth terminal is broadcasted in calculating the PF scheduling priority.

As shown in Equation 8, the base station may determine the scheduling priority of the terminal by reflecting the MCS _new for controlling the RoT of the neighboring base station to the average data rate of the n-th terminal.

The following description describes the configuration of a base station for allocating uplink resources of a terminal through uplink scheduling using RoTs and path loss information of neighboring base stations.

2 is a block diagram of a base station in a wireless communication system according to the present invention.

As shown in FIG. 2, the base station includes a duplexer 200, a receiving device 210, a scheduler 220, a wired interface 221, and a transmitting device 230.

The duplexer 200 transmits a transmission signal provided from the transmission device 230 through an antenna according to a duplexing method, and provides a reception signal from the antenna to the reception device 210. For example, when using a time division duplex scheme, the duplexer 200 transmits a transmission signal provided from the transmission apparatus 230 through an antenna during a transmission interval. Meanwhile, the duplexer 200 provides a reception signal from the antenna to the reception device 210 during the reception period.

The receiving device 210 processes the high frequency signal provided from the duplexer 200. For example, when using Orthogonal Frequency Division Multiplexing (OFDM), the receiver 310 includes a radio frequency (RF) processing module, an OFDM demodulation module, a decoding module, a message processing module, and the like. It is composed by. In this case, the RF processing module converts the high frequency signal RF received from the duplexer 200 into a baseband signal. The OFDM demodulation module converts a time domain signal provided from the RF processing module into a signal in frequency domain through a Fast Fourier Transform (FFT). The decoding module demodulates and decodes the signal provided from the OFDM demodulation module according to a corresponding modulation level. The message processing module extracts a control message included in the signal provided from the demodulation module and transmits the control message to the scheduler 220.

The scheduler 220 allocates resources to terminals for providing a service through scheduling. For example, the scheduler 220 performs uplink scheduling using RoT information of neighboring base stations acquired through the wired interface 221. In this case, as shown in FIG. 1, the scheduler 220 performs uplink scheduling by considering neighboring base stations with respect to inter-cell interference. That is, the scheduler 220 determines the maximum tone transmit power of the terminals in consideration of RoTs of neighboring base stations, determines the uplink MCS level and the data burst size, and then determines the scheduling priority.

In addition, the scheduler 220 controls to periodically transmit its RoT to neighbor base stations via the backhaul.

The wired interface 221 transmits and receives signals with neighbor base stations through a backhaul network.

The transmitter 230 includes a message generator 231 and a transmitter 233.

The message generator 231 generates a resource allocation message for terminals allocated resources by the scheduler 220. In this case, the resource allocation message includes information such as the size of the burst, MCS level and tone transmission power allocated by the scheduler 220 to the terminal.

The transmitter 233 transmits the transmission data and the control message generated by the message generator 231. For example, the transmitter 233 includes a modulation module, an OFDM modulation module, and an RF processing module. In this case, the modulation module codes and modulates the transmission data and the control message according to the modulation level. The OFDM modulation module converts a signal in the frequency domain provided from the modulation module into a signal in the time domain through an inverse fast Fourier transform (IFFT). The RF processing module converts the signal provided from the OFDM modulation module into a high frequency signal.

As described above, the scheduler 220 performs uplink scheduling in consideration of RoTs provided from neighboring base stations. In this case, the scheduler 220 may be configured as shown in FIG. 3.

3 shows a detailed block configuration of the scheduler in the base station according to the present invention.

As shown in FIG. 3, the scheduler 220 includes a storage unit 301, a power determiner 303, an MCS determiner 305, a burst determiner 307, a priority determiner 309, and resource allocation. It is comprised including the part 311.

The storage unit 301 stores RoTs periodically received from neighbor base stations through the wired interface 221.

The power determiner 303 calculates a maximum tone interference power that can be accepted by neighboring base stations in consideration of RoTs of neighboring base stations stored in the storage 301. For example, the power determination unit 303 calculates the magnitude of the tone interference power for each neighboring base station by using Equation (1). For another example, the power determination unit 303 may calculate the magnitude of the tone interference power for each neighboring base station by using Equation (6). As another example, the power determination unit 303 may set the maximum tone interference power of the neighbor base stations using a table including the maximum tone interference power information according to RoT of the neighbor base station.

In addition, the power determination unit 303 calculates the maximum tone transmission power of the terminals using the calculated maximum tone interference power of the adjacent base stations. For example, the power determiner 303 uses the <Equation 2>, the maximum tone power that the n-th terminal can use the smallest value of the tone power that the n-th terminal delivers to the adjacent base stations Set to. For another example, the power determination unit 303 sets the average of the magnitudes of the tone powers transmitted by the nth terminal to the neighbor base stations using the Equation 7 as the maximum tone power available to the nth terminal. It may be.

The MCS determiner 305 determines the maximum MCS level that terminals can use in consideration of the maximum CINR when transmitting data using the maximum tone transmit power determined by the power determiner 303.

The burst determining unit 307 compares the remaining uplink resources that can be allocated to the terminals with the size of the burst that can be transmitted when the terminals use the MCS level determined by the MCS determining unit 305. Determine the size of the burst to allocate. For example, the burst determiner 307 determines the size of a burst to be allocated to each terminal by using Equation 4.

The priority determiner 309 determines the scheduling priority of each terminal by using a difference between the maximum data rate and the average data rate that the terminal can transmit. For example, the priority determiner 309 considers the MCS level of the terminals determined by the MCS determiner 305 and the burst size of the terminals determined by the burst determiner 307 as shown in Equation 5 below. To determine the scheduling priority for each terminal. For another example, the priority determiner 309 may be configured by considering the MCS level of the terminals determined by the MCS determiner 305 and the average data rate for each terminal, as shown in Equation (8). Scheduling priority for may be determined. Here, the scheduling priority indicates an order in which the base station allocates resources through uplink scheduling.

The resource allocator 311 allocates a resource having a size determined by the burst determiner 307 to a terminal having a highest scheduling priority.

Although not shown, the scheduler 220 further includes a controller for controlling uplink scheduling. The controller determines whether to continuously perform uplink scheduling in consideration of the remaining uplink resources after allocating resources to the terminal having the highest scheduling priority in the resource allocator 311. For example, when uplink resources that can be allocated to other terminals remain, the controller controls to continuously perform uplink scheduling. In this case, the controller controls the burst determiner 307 to recalculate the magnitude of the burst allocated to the terminals that do not allocate resources. That is, the size of the remaining uplink resource (RemainingSlot) of Equation (4) is changed by allocating the resource to the terminal having the highest priority, so that the control unit again determines the size of the burst allocated to the terminals that do not allocate the resource. Control to calculate.

On the other hand, if there is no uplink resource that can be allocated to the other terminals, the control unit controls to terminate the uplink scheduling.

In the above-described embodiment, the scheduler 220 includes a storage unit 301 for storing RoT information of neighbor base stations.

In another embodiment, the storage unit 301 may be configured separately from the scheduler 220.

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.

1 is a diagram illustrating an uplink scheduling procedure in a base station according to an embodiment of the present invention;

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

3 illustrates a detailed block configuration of a scheduler in a base station according to the present invention.

Claims (28)

A method for allocating uplink resources in a base station of a wireless communication system, Identifying a magnitude of intercell interference of at least one neighboring base station; Determining a maximum transmit power for at least one terminal in consideration of the magnitude of intercell interference with respect to the at least one neighboring base station; Determining a Modulation and Coding Scheme (MCS) level for each terminal in consideration of the maximum transmit power for the at least one terminal; Determining a size of a resource to be allocated to each terminal by comparing the MCS level for each terminal and the amount of uplink resources that can be allocated to the terminal for providing a service; Determining a scheduling priority for each terminal in consideration of the MCS level and resource size for each terminal; And allocating a resource of the determined size to a terminal having a highest scheduling priority. The method of claim 1, After allocating the resources, checking whether the resources can be allocated to at least one terminal that has not allocated the resources. If resources can be allocated to at least one terminal that has not allocated resources, the process proceeds to determining the size of resources to be allocated to each terminal, and re-sizes the resources to be allocated to terminals that have not allocated resources. Determining. 3. The method of claim 2, The method may further include transmitting resource allocation information to the terminals to which the resource is allocated, when the resource cannot be allocated to the at least one terminal that has not allocated the resource. The method of claim 1, Checking the magnitude of the inter-cell interference, And receiving a rise of thermal (RoT) periodically transmitted by at least one neighboring base station. The method of claim 1, The determining of the maximum transmission power, Determining a maximum interference power that can be accepted by the at least one neighboring base station in consideration of RoT for at least one neighboring base station; Determining a maximum transmit power for at least one terminal in consideration of the maximum interference power of the at least one neighboring base station. The method of claim 5, The process of determining the maximum interference power, Determining the maximum interference power that the at least one neighboring base station can accept to vary linearly with the RoT for at least one neighboring base station. The method of claim 5, The process of determining the maximum interference power, Periodically comparing RoTs with reference RoTs for at least one neighboring base station and periodically increasing or decreasing the maximum interference power that the at least one neighboring base station can accept. The method of claim 5, The process of determining the maximum interference power, Selecting the maximum tone interference power according to the RoT of the at least one neighboring base station in a table including the maximum tone interference power information according to the RoT of the neighboring base station. The method of claim 5, The determining of the maximum transmission power, Determining a maximum transmit power for the terminal based on a minimum value of the maximum tone interference powers of at least one neighboring base station. The method of claim 5, The determining of the maximum transmission power, Determining a maximum transmit power for the terminal by averaging the maximum tone interference powers of at least one neighboring base station. The method of claim 1, The process of determining the MCS level, Calculating a maximum signal-to-interference and noise ratio when the at least one terminal transmits data at the maximum transmission power; And comparing the maximum signal-to-interference and noise ratio with the signal-to-interference and noise ratio according to the MCS level available to each terminal to determine the MCS level for each terminal. The method of claim 1, Determining the scheduling priority, Determining a maximum data rate for each terminal in consideration of the MCS level and resource size for each terminal; Determining a scheduling priority for each terminal in consideration of the difference between the maximum data rate and the average data rate for each terminal. The method of claim 1, Determining the scheduling priority, Determining a scheduling priority for each terminal in consideration of the MCS level for each terminal and the average transmission rate for each terminal. An apparatus for allocating uplink resources in a base station of a wireless communication system, A wired interface for transmitting and receiving signals to and from at least one neighboring base station through a wired network; A scheduler for allocating resources to terminals through uplink scheduling considering the magnitude of interference between cells of at least one neighboring base station provided through the wired interface; And a transmitting device for transmitting the resource allocation information to the terminals. 15. The method of claim 14, The wired interface receives a rise of thermal (RoT) periodically transmitted by at least one neighboring base station, And periodically transmitting the RoT measured by the scheduler to the at least one neighboring base station. 15. The method of claim 14, The scheduler, A power determiner for determining a maximum transmit power for at least one terminal in consideration of the magnitude of inter-cell interference with respect to the at least one neighbor base station; An MCS determination unit for determining a modulation and coding scheme (MCS) level for each terminal in consideration of the maximum transmission power for the at least one terminal; A resource determination unit for comparing the MCS level for each terminal with the amount of uplink resources that can be allocated to the terminal for providing a service and determining the size of the resource to be allocated to each terminal; A priority determining unit for determining a scheduling priority for each terminal in consideration of the MCS level and the size of the resource for each terminal; And a resource allocator for allocating the resource of the determined size to the terminal having the highest scheduling priority. The method of claim 16, The scheduler may further include a controller configured to determine whether to allocate the resource to at least one terminal that has not allocated the resource and to continue uplink scheduling after allocating the resource. . The method of claim 17, The controller may control to re-determine the size of the resource to be allocated to the terminals that have not allocated the resource when the resource may be allocated to the at least one terminal that has not allocated the resource. The method of claim 16, The power determining unit determines the maximum interference power that the at least one neighboring base station can accept in consideration of RoT for at least one neighboring base station, The maximum transmission power for at least one terminal is determined in consideration of the maximum interference power of the at least one neighboring base station. The method of claim 19, And the power determining unit determines a maximum interference power that can be accepted by the at least one neighboring base station so as to linearly change according to RoT for at least one neighboring base station. The method of claim 19, And the power determiner periodically compares RoTs of at least one neighboring base station with a reference RoT to periodically increase or decrease the maximum interference power that can be accepted by the at least one neighboring base station. The method of claim 19, And the power determining unit selects the maximum tone interference power according to the RoT of the at least one neighboring base station from a table including the maximum tone interference power information according to the RoT of the neighboring base station. The method of claim 19, The power determining unit, characterized in that for determining the maximum transmission power for the terminal the minimum value of the maximum tone interference power of at least one neighboring base station. The method of claim 19, The power determination unit, characterized in that for determining the maximum transmission power for the terminal by the average of the maximum tone interference power of at least one neighboring base station. The method of claim 16, The MCS determiner may compare the maximum signal-to-interference and noise ratio when the at least one terminal transmits data at the maximum transmission power with the signal-to-interference and noise ratio according to the MCS level that each terminal can use, and thus the MCS for each terminal. Device for determining the level. The method of claim 16, The priority determiner determines the scheduling priority for each terminal in consideration of the difference between the maximum data rate and the average data rate for each terminal determined in consideration of the MCS level and resource size for each terminal. Characterized in that the device. The method of claim 16, And the priority determiner determines a scheduling priority for each terminal in consideration of the MCS level for each terminal and the average data rate for each terminal. 15. The method of claim 14, And a storage unit for storing the magnitude of the inter-cell interference for at least one neighboring base station provided through the wired interface.

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