JP5479566B2 - Wireless terminal and wireless communication method - Google Patents

Description

  The present invention relates to a radio terminal and a radio communication method capable of assigning a communication channel to a radio base station in a radio communication system.

  In a wireless communication system, a wireless base station forms a cell that is a communicable area of itself, assigns a communication channel to a wireless terminal located in the cell, and performs wireless communication with the wireless terminal via the assigned communication channel. Run. In general, a radio base station assigns communication channels having different frequencies between adjacent cells to radio terminals to prevent interference.

  On the other hand, in order to improve frequency utilization efficiency and cell throughput, a part of the frequency used by the radio base station is made the same between adjacent cells, and other radio base stations or radio terminals (hereinafter referred to as “interference sources”) ), A technique called partial frequency reuse (FFR) that intentionally uses a communication channel affected by interference has been proposed (see, for example, Patent Document 1).

  In such FFR, the radio base station has a large influence of interference from an interference source on a radio terminal having good reception quality such as reception SINR, specifically, a radio terminal located near the center of a cell. One communication channel is allocated. The first communication channel is a communication channel in which the same frequency is used between adjacent cells.

  Also, the radio base station assigns a second communication channel that is less affected by interference from the interference source to radio terminals with poor reception quality, specifically, radio terminals located near the cell edge. The second communication channel is a communication channel in which different frequencies are used between adjacent cells.

Special table 2008-507215 gazette ([summary] etc.)

  By the way, in recent years, with the development of signal processing technology, it has become possible to eliminate the influence of interference in radio terminals and radio base stations. However, the reality is that there is a mixture of high interference removal performance (hereinafter referred to as interference removal performance) and low interference removal performance.

  For this reason, in the conventional method in which the first communication channel or the second communication channel is assigned only according to the reception quality, appropriate channel assignment may not be possible. For example, when a large number of wireless terminals are concentrated in the vicinity of the cell edge, there are cases in which the second channel that can be allocated is insufficient and the first channel that can be allocated remains in the conventional channel allocation method.

  Therefore, the conventional channel allocation method has a problem that the frequency use efficiency and the cell throughput cannot always be improved.

  Therefore, the present invention provides a radio terminal and a radio communication method that enable channel allocation that can maximize the interference cancellation performance of a radio terminal or radio base station, and that can further improve frequency utilization efficiency and cell throughput. The purpose is to provide to do.

  In order to solve the above-described problems, the present invention has the following features. First, the first feature of the present invention is that either the first communication channel that is affected by interference from an interference source or the second communication channel that is less affected by interference from the interference source than the first communication channel. Is a wireless terminal that is assigned by the base station and performs wireless communication with the base station via the assigned communication channel, and has the capability of removing the influence of interference in at least one of the wireless terminal or the wireless base station. The gist is to perform wireless communication with the wireless base station via the first communication channel or the second communication channel assigned by the wireless base station based on a certain interference removal performance.

  The second feature of the present invention is that either the first communication channel that is affected by interference from an interference source or the second communication channel that is less affected by interference from the interference source than the first communication channel is a base. A wireless communication method of a wireless terminal that is assigned by a station and performs wireless communication with the base station via an assigned communication channel, and removes the influence of interference in at least one of the wireless terminal and the wireless base station And performing wireless communication with the wireless base station via the first communication channel or the second communication channel assigned by the wireless base station based on interference cancellation performance that is performance. .

  According to the present invention, it is possible to provide a radio terminal and a radio communication method that enable channel allocation that can maximize the interference cancellation performance of a radio terminal or a radio base station, and that can further improve frequency use efficiency and cell throughput. it can.

1 is a schematic configuration diagram of a radio communication system according to an embodiment of the present invention. It is a figure which shows the example of a division | segmentation of the resource which the wireless base station which concerns on embodiment of this invention uses for downlink data communication. It is a block diagram which shows schematic structure of the wireless base station which concerns on embodiment of this invention. It is a block diagram which shows the detailed structure of the wireless base station which concerns on embodiment of this invention. It is a figure which shows an example of the threshold value information which the threshold value information storage part which concerns on embodiment of this invention memorize | stores. It is a sequence diagram which shows schematic operation | movement of the radio | wireless communications system which concerns on embodiment of this invention. It is a flowchart which shows detailed operation | movement of the wireless base station which concerns on embodiment of this invention.

  Next, regarding the radio communication system according to the embodiment of the present invention, (1) overall schematic configuration, (2) configuration of radio base station, (3) example of threshold information, (4) operation of radio communication system, (5) ) Operation and effect, (6) Other embodiments will be described in this order. In the description of the drawings in the following embodiments, the same or similar parts are denoted by the same or similar reference numerals.

(1) Overall Schematic Configuration First, an overview of the radio communication system according to the present embodiment will be described in the order of (1.1) schematic configuration of the radio communication system and (1.2) an example of FFR.

(1.1) Schematic Configuration of Radio Communication System FIG. 1 is a schematic configuration diagram of a radio communication system 10 according to the present embodiment. In this embodiment, for convenience of explanation, a radio communication system 10 having three radio base stations (radio base station BS1, radio base station BS2, and radio base station BS3) will be described. However, the number of radio base stations is larger. Also good.

  The radio communication system 10 employs an orthogonal frequency division multiple access (OFDMA) system, which is one of multicarrier communication systems using a plurality of carriers. In the OFDMA scheme, a communication channel using a plurality of carriers is dynamically assigned to a wireless terminal. A communication channel is defined by a combination of frequency and time.

  In the radio communication system 10, both the transmission side and the reception side have a plurality of antennas, and radio signals can be transmitted and received using the plurality of antennas. That is, the wireless communication system 10 has introduced MIMO (Multi-Input Multi-Output) technology.

  In the MIMO technology, a plurality of signal sequences using the same frequency band are simultaneously transmitted via a plurality of antennas on the transmission side, and the signal sequence is received via a plurality of antennas on the reception side and separated into signal sequences. . There are various types of signal processing techniques used for signal sequence separation, and the higher the signal separation method, the higher the interference removal performance on the receiving side.

  In addition, the transmission side may support adaptive array transmission. In adaptive array transmission, the transmission side directs the transmission directivity of an antenna unit (array antenna) composed of a plurality of antennas in the direction of the reception side. Specifically, radio waves from a plurality of antennas are spatially synthesized, and directivity (a region having a strong electrolytic distribution) is directed toward the receiving side. When the transmission side supports adaptive array transmission, the reception SINR characteristic on the terminal side is improved, and the tolerance to interference is further improved.

  The radio base station BS1 forms a cell C1, the radio base station BS1 forms a cell C2, and the radio base station BS1 forms a cell C3. A radio terminal MS is located in the cell C1. Although only one radio terminal MS is illustrated in FIG. 1, in reality, a large number of radio terminals are located in each of the cell C1, the cell C2, and the cell C3.

  In the present embodiment, the radio base stations BS1 to BS3 execute channel allocation based on the above-described FFR. In FFR, each radio base station divides resources (frequency and time) that can be used for radio communication into a multi-interference zone and a low-interference zone, and configures a communication channel using these zones. For example, a radio base station allocates a communication channel configured using a multi-interference zone to a certain radio terminal, and allocates a communication channel configured using a low-interference zone to another radio terminal.

  The multi-interference zone is a zone having the same frequency and time in the radio base stations BS1 to BS3. The frequency reuse factor RF (Reuse Factor) in the multi-interference zone is 1, and in the following, this zone will be referred to as the Reuse 1 zone. The low interference zone is a zone where the frequency and time are different in the radio base stations BS1 to BS3. In the present embodiment, the frequency repetition usage rate RF in the low interference zone is 3, and in the following, this zone is referred to as a Reuse 3 zone. A communication channel configured using the Reuse 1 zone is referred to as a multi-interference channel (first communication channel), and a communication channel configured using the Reuse 3 zone is referred to as a low-interference channel (second communication channel).

  In the following, a case will be mainly described where the radio base station BS1 allocates a communication channel to the radio terminal MS in downlink (DL) communication. The radio base station BS1 has a multi-interference channel, a radio base station BS2, and a radio base station that are affected by interference from the radio base station BS2 and the radio base station BS3 according to reception quality (SINR) notified from the radio terminal MS. One of the low-interference channels that is less affected by interference from the BS 3 than the multi-interference channel is assigned to the radio terminal MS.

(1.2) Example of FFR Next, an example of FFR applied to the radio communication system 10 will be described with reference to FIGS. 1 and 2. FIG. 2 shows an example of dividing resources (frequency and time) used by the radio base station BS1 for DL data communication.

  As shown in FIG. 2, the radio base station BS1 sets a zone of the frequency F0 that the radio base stations BS1 to BS3 commonly use at time T1 as a Reuse 1 zone. Radio base station BS1 sets the zone of frequency F1 at time T2 as the Reuse 3 zone. The zone of the frequency F2 at time T2 cannot be used by the radio base station BS1 because many radio base stations, that is, the radio base station BS2 and the radio base station BS3, are used as the Reuse 3 zone.

  In the example of FIG. 2, the Reuse 3 zone used by the radio base station BS1 is smaller than the Reuse 1 zone. That is, the resource amount in the Reuse 1 zone is larger than the resource amount in the Reuse 3 zone. For this reason, the radio base station BS1 can allocate more resources (frequency and time) to the radio terminal when using the Reuse1 zone than the Reuse3 zone.

  In normal FFR, when the radio base station BS1 allocates a communication channel to a radio terminal with good reception quality located near the center C1a of the cell C1, the radio base station BS1 identifies the unallocated part of the Reuse1 zone, A multi-interference channel consisting of at least a part is allocated. In addition, when the radio base station BS1 allocates a communication channel to a radio terminal with poor reception quality located near the cell edge C1b of the cell C1, the radio base station BS1 identifies an unallocated part of the Reuse3 zone, and at least a part of the identified unallocated part Assign a low interference channel consisting of

  In addition to such channel allocation, the radio base station BS1 performs channel allocation in consideration of interference removal performance of the radio base station BS1 and the radio terminal MS. For example, even when the radio base station BS1 assigns a communication channel to the radio terminal MS located in the cell edge vicinity C1b, when the radio base station BS1 or the radio terminal MS determines that the interference removal performance is high, the multi-interference channel Are assigned to the radio terminal MS.

(2) Configuration of Radio Base Station Next, the configuration of the radio base station BS1 will be described in the order of (2.1) schematic configuration of the radio base station and (2.2) detailed configuration of the radio base station. Note that the radio base station BS2 and the radio base station BS3 have the same configuration as that of the radio base station BS1, and thus the description of the radio base station BS2 and the radio base station BS3 is omitted.

(2.1) Schematic Configuration of Radio Base Station FIG. 3 is a block diagram showing a schematic configuration of the radio base station BS1. As illustrated in FIG. 3, the radio base station BS1 includes an antenna unit 101, a radio communication unit 110, a control unit 120, a storage unit 130, and an I / F unit 140.

  The antenna unit 101 includes a plurality of antennas. The antenna unit 101 is configured as an array antenna, for example.

  The radio communication unit 110 performs radio communication with the radio terminal MS using the OFDMA scheme. Specifically, the wireless communication unit 110 includes a low noise amplifier, a power amplifier, an up converter, a down converter, a baseband processor, and the like, and transmits and receives wireless signals according to the OFDMA scheme. Further, the wireless communication unit 110 executes signal processing using the above-described MIMO technology.

  The control unit 120 is configured by a CPU, for example, and controls various functions provided in the radio base station BS1. The storage unit 130 is configured by a memory, for example, and stores various types of information used for control in the radio base station BS1. The I / F unit 140 is wired to a backbone network (not shown).

(2.2) Detailed Configuration of Radio Base Station FIG. 4 is a block diagram showing a detailed configuration of the radio base station BS1, specifically, functional blocks of the control unit 120 and the storage unit 130. FIG. 4 shows only functional blocks related to the present invention.

  As illustrated in FIG. 4, the control unit 120 includes a performance determination unit 121, a traffic amount acquisition unit 122, a quality acquisition unit 123, and a channel allocation unit 125. The storage unit 130 includes a threshold information storage unit 131 and an allocation information storage unit 132.

  The performance determination unit 121 determines an interference removal performance that is a performance for removing the influence of interference in each of the wireless terminal MS and the wireless base station BS1. The performance determination unit 121 determines the interference removal performance of the radio terminal MS based on the notification from the radio terminal MS. Or the performance determination part 121 may determine the interference removal performance of the radio | wireless terminal MS based on the notification from the management server (not shown) etc. which were connected to the backbone network. The performance cancellation unit 121 can determine the interference cancellation performance of the radio base station BS1 by storing the interference cancellation performance of the radio base station BS1 in the storage unit 130 in advance.

  The traffic volume acquisition unit 122 acquires the traffic volume (total traffic volume) transmitted and received by the radio base station BS1 in radio communication. The traffic volume is not limited to the current traffic volume, but may be the traffic volume for the most recent hour. For example, in DL communication, the traffic volume acquisition unit 122 can acquire the traffic volume by measuring the amount of untransmitted data stored in the transmission buffer provided in the storage unit 130. Alternatively, the traffic amount acquisition unit 122 may acquire the number of wireless terminals that are performing wireless communication with the wireless base station BS1 as the traffic amount.

  The quality acquisition unit 123 acquires the reception quality of the radio signal received by the radio terminal MS from the radio base station BS1. The radio base station BS1 periodically transmits a known signal (such as a pilot signal) in the radio terminal MS into the cell C1, and the radio terminal MS measures the reception quality when the signal is received and measures The received reception quality is notified to the radio base station BS1. The quality acquisition unit 123 can acquire the reception quality in the radio terminal MS from the notification. As reception quality, not only the above signal-to-interference noise power ratio (SINR) but also reception signal electric field strength (RSSI) may be used.

  The channel allocating unit 125 determines whether or not the multi-interference channel or the interference canceling performance determined by the performance determining unit 121, the traffic amount acquired by the traffic amount acquiring unit 122, and the reception quality acquired by the quality acquiring unit 123 One of the few interference channels is assigned to the radio terminal MS.

  Specifically, the channel assignment unit 125 assigns the multi-interference channel to the radio terminal MS with priority over the low-interference channel as the interference cancellation performance determined by the performance determination unit 121 is higher. Further, the channel assignment unit 125 assigns the less interference channel to the radio terminal MS with higher priority than the more interference channel as the interference removal performance determined by the performance determination unit 121 is lower.

  Furthermore, the channel allocation unit 125 includes a threshold control unit 126, a comparison unit 127, and an allocation execution unit 128.

  The comparison unit 127 compares the reception quality acquired by the quality acquisition unit 123 with the threshold Th. The threshold control unit 126 controls the threshold Th according to the interference removal performance determined by the performance determination unit 121 and the traffic amount acquired by the traffic amount acquisition unit 122.

  The allocation execution unit 128 allocates either the multi-interference channel or the low-interference channel to the radio terminal MS according to the comparison result by the comparison unit 127. Specifically, the assignment execution unit 128 assigns the multi-interference channel to the radio terminal MS when the reception quality exceeds the threshold Th, and assigns the low-interference channel to the radio terminal MS when the reception quality falls below the threshold Th.

  The assignment execution unit 128 refers to the assignment information stored in the assignment information storage unit 132 and performs channel assignment. Allocation information is information regarding allocated resources or unallocated resources. When executing the channel allocation, the allocation execution unit 128 sets the allocated communication channel resource as “already allocated” and updates the allocation information.

  The threshold control unit 126 controls the threshold Th with reference to the threshold information stored in the threshold information storage unit 131. The threshold control unit 126 lowers the threshold as the interference removal performance is higher, and increases the threshold as the interference removal performance is lower. As a result, the higher the interference cancellation performance, the easier the multi-interference channel is assigned to the radio terminal MS, and the lower the interference cancellation performance, the easier the less interference channel is assigned to the radio terminal MS.

(3) Example of Threshold Information FIG. 5 is a diagram illustrating an example of threshold information stored in the threshold information storage unit 131.

  In FIG. 5, the higher the “priority” item (the smaller the value), the higher the priority of the multi-interference channel, that is, the lower the threshold value.

  Priority 1 with the highest priority is when the receiving side (wireless terminal MS) supports MLD (Maximum Likelihood Detection), which is one of signal separation methods, and has the highest interference cancellation performance. However, when the transmission side (radio base station BS1) supports adaptive array transmission, the interference cancellation characteristic is further enhanced. In addition, since MLD estimates the maximum likelihood signal from all signal candidates, the amount of calculation increases. Therefore, the wireless terminal MS with low processing capability cannot be equipped with the MLD.

  Priorities 2 and 3 are when the transmitting side (radio base station BS1) supports adaptive array transmission and the receiving side (radio terminal MS) supports MMSE (Minimum Mean Square Error), which is one of the signal separation methods. It is. In FIG. 5, multiple antenna sounding is a technique for improving the accuracy of adaptive array transmission.

  Priority 4 is a case where the transmitting side (radio base station BS1) does not support adaptive array transmission and the receiving side (radio terminal MS) supports MMSE (Minimum Mean Square Error). When adaptive array transmission is not supported, CDD (Cyclic Delay Diversity) is used to obtain a frequency diversity effect by changing the timing between each system of the OFDM modulated signal.

  ZF (Zero forcing) at the priorities 5 and 6 is one of signal separation methods, and is an algorithm having lower interference removal performance than MLD and MMSE. MRC (Maximum Ratio Combining) at the priorities 7 and 8 is an algorithm that only synthesizes signals received by the respective antennas at the maximum ratio, and has low interference removal performance.

(4) Operation of Radio Communication System Next, the operation of the radio communication system 10 will be described in the order of (4.1) schematic operation of the radio communication system and (4.2) detailed operation example of the radio base station.

(4.1) Schematic Operation of Radio Communication System FIG. 6 is a sequence diagram showing a schematic operation of the radio communication system 10.

  In step S101, the radio terminal MS measures the reception quality of the radio signal received from the radio base station BS1. Here, it is assumed that the radio terminal MS measures the reception SINR as reception quality.

  In step S102, the radio terminal MS notifies the radio base station BS1 of the reception quality (reception SINR) measured in step S101. At that time, the radio terminal MS notifies the radio base station BS1 of information for identifying an interference cancellation algorithm (for example, MLD or MMSE) supported by the radio terminal MS. However, the radio terminal MS may notify the radio base station BS1 of a value representing the high level of interference removal performance without being limited to such identification information.

  In step S103, the radio base station BS1 acquires the amount of traffic transmitted and received by the radio base station BS1.

  In step S104, the radio base station BS1 executes channel assignment processing. Details of the channel assignment processing will be described later.

  In step S105, the radio base station BS1 notifies the radio terminal MS of the communication channel assigned in step S104. After Step S105, the radio base station BS1 and the radio terminal MS perform radio communication via the communication channel assigned to the radio terminal MS.

(4.2) Detailed Operation Example of Radio Base Station FIG. 7 is a flowchart showing detailed operation of the radio base station BS1, specifically, details of step S104 in FIG.

  In step S201, the threshold control unit 126 determines whether or not both the radio terminal MS and the radio base station BS1 have the interference cancellation performance based on the interference cancellation performance determined by the performance determination unit 121. When both the radio terminal MS and the radio base station BS1 do not have interference removal performance, the threshold control unit 126 sets a predetermined standard threshold Th in the comparison unit 127.

  If at least one of the radio terminal MS or the radio base station BS1 has interference cancellation performance, the process proceeds to step S202. In step S202, the threshold control unit 126 determines whether or not the traffic amount acquired by the traffic amount acquisition unit 122 is below a predetermined amount. When the traffic amount is lower than the predetermined amount, the threshold control unit 126 sets a predetermined standard threshold Th in the comparison unit 127.

  If the traffic amount exceeds the predetermined amount, the process proceeds to step S204. In step S204, the threshold control unit 126 refers to the threshold information stored in the threshold information storage unit 131, and determines the threshold Th corresponding to the interference removal performance determined by the performance determination unit 121.

  In step S205, the threshold control unit 126 adjusts the threshold Th determined in step S204 according to the traffic volume acquired by the traffic volume acquisition unit 122.

  Here, the threshold value control unit 126 decreases the threshold value Th as the traffic volume increases, and increases the threshold Th as the traffic volume decreases. As a result, the larger the traffic volume, the easier it is to assign a multi-interference channel, and the smaller the traffic volume, the easier it is to assign a low-interference channel.

  In step S206, the comparison unit 127 compares the reception quality (reception SINR) acquired by the quality acquisition unit 123 with the threshold Th.

  If the reception quality (reception SINR) is higher than the threshold value Th, the process proceeds to step S207. In step S207, the assignment execution unit 128 assigns the multi-interference channel to the radio terminal MS.

  If the reception quality (reception SINR) is equal to or less than the threshold Th, the process proceeds to step S208. In step S208, the assignment execution unit 128 assigns the low interference channel to the radio terminal MS.

(5) Operation / Effect As described above, the channel assignment unit 125 gives priority to the multi-interference channel over the low-interference channel as the interference cancellation performance in at least one of the radio terminal MS or the radio base station BS1 increases. Assign to MS. Therefore, channel allocation that can maximize the interference cancellation performance of the radio terminal MS or the radio base station BS1 is possible, and the frequency utilization efficiency and the cell throughput can be further improved.

  In the present embodiment, the channel assignment unit 125 assigns the less interference channel to the radio terminal MS in preference to the more interference channel as the interference cancellation performance in at least one of the radio terminal MS or the radio base station BS1 is lower. For this reason, when the interference removal performance of the radio terminal MS or the radio base station BS1 is low, the radio terminal MS can stably perform radio communication by allocating the low interference channel to the radio terminal MS.

  In the present embodiment, the channel allocating unit 125 selects either the multi-interference channel or the low-interference channel based on the interference removal performance determined by the performance determination unit 121 and the reception quality acquired by the quality acquisition unit 123. Assign to the radio terminal MS. Specifically, the threshold control unit 126 of the channel allocating unit 125 lowers the threshold compared with the reception quality as the interference cancellation performance is higher, and increases the threshold as the interference cancellation performance is lower. Therefore, channel allocation considering both reception quality and interference removal performance is possible, and the communication quality in the radio terminals around the cell edge can be further stabilized while realizing improvement in frequency utilization efficiency and cell throughput.

  In the present embodiment, the channel allocation unit 125 performs channel allocation based on the traffic volume acquired by the traffic volume acquisition unit 122 as well as the interference cancellation performance and reception quality. Specifically, when it is determined that the traffic volume is lower than a predetermined amount, the channel allocation unit 125 omits the channel allocation based on the interference removal performance and executes the channel allocation based on the reception quality. When the amount of traffic is small, it is possible to reduce processing impossibility of the radio base station BS1 by assigning the same channel assignment as the conventional one.

  Further, the threshold control unit 126 of the channel allocating unit 125 lowers the threshold Th as the traffic volume increases, and increases the threshold Th as the traffic volume decreases. That is, the larger the traffic volume, the easier it is to assign a multi-interference channel, and the smaller the traffic volume, the easier it is to assign a low-interference channel. As described above, when the resource amount of the Reuse 1 zone is larger than the resource amount of the Reuse 3 zone and the traffic amount is large, the resource amount of the Reuse 1 zone is surplus, but the resource amount of the Reuse 3 zone is insufficient. Therefore, such a problem can be avoided by actively allocating a multi-interference channel when the amount of traffic is large.

(6) Other Embodiments As described above, the present invention has been described according to the embodiment. However, it should not be understood that the description and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  For example, in the above-described embodiment, the channel allocating unit 125 performs the interference removal performance determined by the performance determining unit 121, the traffic amount acquired by the traffic amount acquiring unit 122, and the reception quality acquired by the quality acquiring unit 123. Based on the above, either the multi-interference channel or the low-interference channel is assigned to the radio terminal MS.

  However, the channel allocation unit 125 may allocate either the multi-interference channel or the low-interference channel to the radio terminal MS based only on the interference cancellation performance determined by the performance determination unit 121. In this case, the channel allocation unit 125 may allocate a multi-interference channel when the interference cancellation performance is higher than a predetermined level, and allocate a low-interference channel when the interference cancellation performance is lower than the predetermined level.

  Alternatively, the channel allocation unit 125 may allocate either the multi-interference channel or the low-interference channel to the radio terminal MS based on the interference cancellation performance and the reception quality without considering the traffic amount. In this case, steps S202 and S205 in FIG. 7 are not necessary.

  In the embodiment described above, the radio base station BS1 performs channel assignment in consideration of the interference cancellation performance of both the radio base station BS1 and the radio terminal MS. However, only one of the radio base station BS1 and the radio terminal MS is performed. Channel allocation may be performed in consideration of the interference cancellation performance. In this case, in the example of the threshold information stored in the threshold information storage unit 131 (FIG. 5), the items on both the transmission side (radio base station BS1) and the reception side (radio terminal MS) may not be provided.

  In the above-described embodiments, DL channel assignment has been mainly described, but the present invention can also be applied to uplink (UL) channel assignment.

  In the above-described embodiment, the wireless communication standard of the wireless communication system 10 has not been described in particular. For example, LTE (Long Term Evolution), or the UMB (Ultra Mobile Broadband) under development of the standard in 3GPP2, the wireless communication system 10 may be configured.

  In addition, it is possible to mount each processing procedure described above as a computer program and cause the radio base station to execute the computer program.

  Thus, it should be understood that the present invention includes various embodiments and the like not described herein. Therefore, the present invention is limited only by the invention specifying matters in the scope of claims reasonable from this disclosure.

  MS ... wireless terminal, BS1 to BS3 ... wireless base station, 10 ... wireless communication system, 101 ... antenna unit, 110 ... wireless communication unit, 120 ... control unit, 121 ... performance determination unit, 122 ... traffic volume acquisition unit, 123 ... Quality acquisition unit, 125 ... I / F unit, 126 ... threshold control unit, 127 ... comparison unit, 128 ... execution unit, 130 ... storage unit, 131 ... threshold information storage unit, 132 ... information storage unit

Claims (2)

Either a first communication channel that is affected by interference from an interference source or a second communication channel that is less affected by interference from the interference source than the first communication channel is assigned by the base station and assigned communication. A wireless terminal for performing wireless communication with the base station via a channel,
Based on said interference removal performance is the ability to eliminate the influence of Oite interference to radio terminal end, the radio with the radio base station via the first communication channel or said second communication channel radio base station is assigned A wireless terminal that performs communication. Either a first communication channel that is affected by interference from an interference source or a second communication channel that is less affected by interference from the interference source than the first communication channel is assigned by the base station and assigned communication. A wireless communication method of a wireless terminal that performs wireless communication with the base station via a channel,
Based on said interference removal performance is the ability to eliminate the influence of Oite interference to radio terminal end, the radio with the radio base station via the first communication channel or said second communication channel radio base station is assigned Performing communication,
A wireless communication method comprising:

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