JP2004032202A - Radio transmitting apparatus and scheduling method - Google Patents

Abstract

An object of the present invention is to reduce deterioration of signal quality due to an interference component and perform good communication.
When performing scheduling, a radio resource control unit reads a mobile station device to be scheduled in each slot from a table, and performs scheduling according to a predetermined algorithm. The table 142 holds, for each slot in the virtual frame, a mobile station device that permits data transmission. Communication quality comparing section 144 compares the communication quality of each mobile station apparatus notified from radio resource control section 130 with a predetermined communication quality, and determines the correspondence between each slot in table 142 and the mobile station apparatus permitting data transmission. It is determined whether or not to change.
[Selection] Fig. 2

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a wireless transmission device and a scheduling method.
[0002]
[Prior art]
Conventionally, as disclosed in, for example, JP-A-11-239152, a scheduling method in the uplink has been studied. In the uplink random access method, if a vacant time occurs in the data channel as a result of scheduling in the uplink random access method, access is performed again during the vacant time to improve uplink transmission efficiency.
[0003]
[Problems to be solved by the invention]
However, in the above-described scheduling method in the uplink, for example, when there is a mobile station device located at a cell edge of an adjacent cell that transmits a signal at the same timing, a signal from the mobile station device may cause interference. As a signal, the quality of the received signal in the base station apparatus deteriorates, and there is a problem that good communication cannot be performed.
[0004]
Hereinafter, a specific example of this problem will be described with reference to FIG.
[0005]
In FIG. 8, base station apparatus 10 determines a signal transmission order for mobile station apparatuses in its own cell including mobile station apparatus 30, and a transmission permission signal for permitting signal transmission to each mobile station apparatus. To perform uplink scheduling. Similarly, the base station device 20 performs scheduling of mobile station devices in the own cell including the mobile station device 40.
[0006]
At this time, if the mobile station device 30 and the mobile station device 40 transmit signals at the same timing as a result of scheduling by the base station device 10 and the base station device 20, the mobile station device 30 Since it is located near, the signal transmitted from the mobile station device 30 occupies a large proportion of the received signal of the base station device 20. In other words, in the reception signal of the base station device 20, the transmission signal of the mobile station device 30 as the interference component occupies a large ratio with respect to the transmission signal of the mobile station device 40 as the desired component. The quality of the received signal in the device 20 is degraded.
[0007]
The present invention has been made in view of such a point, and an object of the present invention is to provide a wireless transmission device and a scheduling method capable of reducing deterioration of signal quality due to an interference component and performing good communication.
[0008]
[Means for Solving the Problems]
The wireless transmission device according to the present invention is configured such that setting means for setting a timing at which data transmission is permitted for each communication partner station according to a communication state in a neighboring cell, and data transmission is permitted at the same timing among the set timings. A configuration is adopted that includes a determination unit that determines a communication partner station to which data is actually transmitted from the communication partner station at the timing, and a transmission unit that transmits a transmission permission signal to the determined communication partner station.
[0009]
According to this configuration, the timing at which data transmission is permitted is set for each communication partner station in accordance with the communication situation in the neighboring cell, and the data is actually transmitted from the communication partner station permitted to transmit data at the same timing. Since the communication partner station is determined and the transmission permission signal is transmitted to the communication partner station, the communication partner station does not transmit the signal at the timing when the interference component from the neighboring cell is large, and the signal quality is deteriorated due to the interference component. Reduction and good communication can be performed.
[0010]
In the wireless transmission apparatus according to the present invention, the setting means may include a table holding slots for which data transmission is permitted for each communication partner station in a virtual frame including a predetermined number of slots, and a communication quality between the communication partner station and the own station. And a communication quality comparing unit for comparing a predetermined communication quality, wherein the table indicates that the communication quality between the communication partner station and the own station is other than the predetermined communication quality as a comparison result of the communication quality comparing unit. In this case, a configuration is adopted in which the slot in which data transmission of the communication partner station is permitted is changed.
[0011]
According to this configuration, the communication quality between the communication partner station and the own station and the predetermined communication quality are compared, and if the communication quality between the communication partner station and the own station is other than the predetermined communication quality, the communication partner station Since the slot that allows data transmission is changed, the timing of data transmission from the partner station can be changed according to the communication quality that changes due to interference components from neighboring cells, reducing the degradation of signal quality due to interference components. And good communication can be performed.
[0012]
In the wireless transmission device according to the present invention, when the communication quality between the communication partner station and the own station is better than a predetermined communication quality, the table may include data of the communication partner station as a comparison result of the communication quality comparison unit. A configuration is adopted in which the slot for which transmission is permitted is changed by one slot in the leading direction in the virtual frame.
[0013]
According to this configuration, when the communication quality between the communication partner station and the own station is better than the predetermined communication quality, the slot in which data transmission of the communication partner station is permitted is shifted by one slot toward the beginning in the virtual frame. Therefore, by performing the same control in the neighboring cells, the communication partner stations that are not likely to interfere with each other in the respective cells simultaneously transmit data in the slot in the leading direction of the virtual frame, and thus the transmission efficiency of the entire system. Can be improved.
[0014]
In the wireless transmission device of the present invention, when the communication quality between the communication partner station and the own station is inferior to a predetermined communication quality as a comparison result of the communication quality comparison unit, the table includes data of the communication partner station. A configuration is adopted in which the slot for which transmission is permitted is changed by one slot in the final direction in the virtual frame.
[0015]
According to this configuration, when the communication quality between the communication partner station and the own station is inferior to the predetermined communication quality, the slot for permitting data transmission of the communication partner station is one slot in the final direction in the virtual frame. Therefore, when the interference component from the neighboring cell is large, the communication partner station can shift the data transmission timing, reduce the degradation of the signal quality due to the interference component, and perform good communication.
[0016]
In the wireless transmission apparatus according to the present invention, the setting unit holds a slot for permitting data transmission for each communication partner station in a virtual frame including a slot corresponding to an area obtained by dividing the own cell according to a distance from the own station. And a distance measuring unit that measures the distance between the communication partner station and the own station, the measured distance, and slot information indicating whether data transmission is permitted in the own cell for each slot in the virtual frame. And a permission slot determination unit that determines a slot for which data transmission is permitted for each communication partner station based on the above-mentioned configuration, and the table is updated based on the determination result of the permission slot determination unit.
[0017]
According to this configuration, the distance between the communication partner station and the own station is measured, and the measured distance and the slot information indicating whether data transmission is permitted in the own cell for each slot in the virtual frame. In order to determine the slot in which data transmission is permitted for each communication partner station based on the communication partner station, the communication partner station that easily causes interference to neighboring cells, in other words, the data transmission of the communication partner station located at the cell edge of the own cell. The timing can be changed for each cell, the degradation of signal quality due to interference components can be reduced, and good communication can be performed.
[0018]
The wireless transmission apparatus of the present invention employs a configuration in which the slot information indicates that data transmission is permitted more frequently in a slot corresponding to an area closer to the own station.
[0019]
According to this configuration, since the slot information indicates that data transmission is permitted more frequently in a slot corresponding to an area closer to the own station, a communication partner station located in an area closer to the own station, in other words, A communication partner station that does not easily interfere with the cell can frequently transmit data, and can prevent an extreme decrease in transmission efficiency.
[0020]
In the wireless transmission device of the present invention, the slot information is a slot corresponding to an area far from the own station, and data transmission is allowed in the own cell for a slot in which data transmission is not allowed in the same slot of a neighboring cell. Is adopted.
[0021]
According to this configuration, the slot information indicates that data transmission is permitted in the own cell for a slot corresponding to an area far from the own station and for which data transmission is not permitted in the same slot of a neighboring cell. Therefore, the data transmission timing of a communication partner station located in an area far from the local station, in other words, a communication partner station that easily causes interference to neighboring cells can be changed for each cell, and signal quality due to interference components can be reduced. Deterioration can be reduced and good communication can be performed.
[0022]
The wireless transmission apparatus of the present invention employs a configuration in which the setting unit sets a timing at which data transmission in an uplink is permitted according to a communication state in a neighboring cell.
[0023]
According to this configuration, in order to set the timing at which data transmission in the uplink is permitted according to the communication conditions in the neighboring cells, signal quality degradation due to interference components is caused for uplink signals from the mobile station apparatus to the base station apparatus. , And good communication can be performed.
[0024]
A base station apparatus according to the present invention employs a configuration including any one of the wireless transmission apparatuses described above.
[0025]
According to this configuration, the same operation and effect as those of any of the above-described wireless transmission devices can be realized in the base station device.
[0026]
A scheduling method according to the present invention comprises the steps of: setting a timing at which data transmission is permitted for each communication partner station according to a communication situation in a neighboring cell; and a communication partner station permitted to transmit data at the same timing among the set timings. And a step of determining a communication partner station to which data is actually transmitted at the timing, and a step of transmitting a transmission permission signal to the determined communication partner station.
[0027]
According to this method, a timing at which data transmission is permitted is set for each communication partner station in accordance with a communication situation in a neighboring cell, and communication is performed in which data is actually transmitted from a communication partner station permitted to transmit data at the same timing. Since the communication partner station is determined and the transmission permission signal is transmitted to the communication partner station, the communication partner station does not transmit the signal at the timing when the interference component from the neighboring cell is large, and the signal quality is deteriorated due to the interference component. Reduction and good communication can be performed.
[0028]
BEST MODE FOR CARRYING OUT THE INVENTION
The gist of the present invention is to prevent a mobile station device located at a position that gives a large interference component to a base station device in a neighboring cell from transmitting signals simultaneously in each cell.
[0029]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0030]
(Embodiment 1)
FIG. 1 is a diagram showing an example of a cell configuration according to Embodiment 1 of the present invention. In the figure, cells of base station apparatus 100, base station apparatus 200, and base station apparatus 300 are close to each other. The base station device 100, the base station device 200, and the base station device 300 are controlled by a control station device (not shown). This control station device transmits data addressed to each mobile station device to the base station device with which it communicates, and transmits data from the mobile station device to the base station device of the communication partner for uplink data transmission. The length (that is, the number of slots) of a transmission unit composed of a predetermined number of slots (in the present embodiment, this is called a “virtual frame”) is notified to the base station apparatus. Thereby, base station apparatus 100, base station apparatus 200, and base station apparatus 300 are synchronized between base station apparatuses.
[0031]
FIG. 2 is a block diagram showing a configuration of base station apparatus 100 according to Embodiment 1. The base station apparatus 100 shown in FIG. 1 includes a radio transmission / reception unit 110, a retransmission control unit 120, a radio resource control unit 130, and a transmission permission slot setting unit 140 including a table 142 and a communication quality comparison unit 144. It is assumed that base station apparatus 200 and base station apparatus 300 have the same configuration.
[0032]
The wireless transmission / reception unit 110 performs data transmission / reception via an antenna and performs predetermined wireless processing (encoding, decoding, modulation / demodulation, and the like). The retransmission control unit 120 temporarily stores data addressed to each mobile station device transmitted from the control station device, and performs retransmission control. Radio resource control section 130 controls radio transmission / reception section 110 and retransmission control section 120 and performs scheduling. Specifically, the radio resource control unit 130 measures communication quality such as throughput, block error rate, minimum transmission rate, or MCS (Modulation Coding Schemes) for data for each mobile station device. The communication quality is notified to the communication quality comparison unit 144 at predetermined intervals. When performing scheduling, the radio resource control unit 130 reads a mobile station device to be scheduled (that is, permits data transmission) in each slot from the table 142 and performs scheduling according to a predetermined algorithm. Further, radio resource control section 130 transmits a transmission permission signal via retransmission control section 120 and radio transmission / reception section 110 to a mobile station apparatus that actually transmits data in each slot.
[0033]
The transmission permission slot setting unit 140 includes a table 142 and a communication quality comparison unit 144. The transmission permission slot setting unit 140 performs virtual communication based on the virtual frame length notified from the control station device and the communication quality measured by the radio resource control unit 130. For each slot in the frame, which mobile station device is permitted to transmit data is set. The table 142 holds, for each slot in the virtual frame, a mobile station device that permits data transmission. Communication quality comparing section 144 compares the communication quality of each mobile station apparatus notified from radio resource control section 130 with a predetermined communication quality, and determines the correspondence between each slot in table 142 and the mobile station apparatus permitting data transmission. It is determined whether or not to change.
[0034]
Next, the operation of setting a transmission permission slot in base station apparatus 100 configured as described above will be described with reference to the flowchart shown in FIG.
[0035]
First, in the initial state, since all mobile station apparatuses with which the base station apparatus 100 communicates are allowed to transmit data in the first slot of the virtual frame (ST1000), the radio resource control unit 130 Scheduling according to the algorithm of the above, the mobile station device to transmit data in the first slot is determined from all the mobile station devices with which communication is performed, and the data transmission in the first slot is performed for the mobile station device. A transmission permission signal indicating permission is transmitted. The mobile station device that has received the transmission permission signal transmits data in the slot (first time slot) for which data transmission is permitted (ST1100). Then, when data is received by wireless transmission / reception section 110, communication quality of data is measured by wireless resource control section 130 (ST1200).
[0036]
Here, radio resource control section 130 determines whether or not a predetermined cycle for updating table 142 has elapsed (ST1300). If the predetermined cycle has not elapsed, radio resource control section 130 continues. Scheduling is performed by 130 and data transmission is performed. On the other hand, if the predetermined period has elapsed, the communication quality measured by the radio resource control unit 130 is notified to the communication quality comparison unit 144, and whether or not this communication quality is within a predetermined range is determined. It is determined by the communication quality comparison unit 144. In this determination, it is first determined whether or not the measured communication quality is equal to or higher than a predetermined range of communication quality (ST1400). If the measured communication quality is not equal to or higher than the predetermined range of communication quality, the communication quality of the predetermined range is determined. It is determined whether or not the following is true (ST1700). Here, “the measured communication quality is equal to or higher than a predetermined range of communication quality” indicates that the communication quality of the received data is excessive, and “the measured communication quality is higher than the predetermined range of communication quality”. The expression "below" indicates that the interference component from the mobile station device located in the neighboring cell is large and the communication quality of the received data is inferior to the required communication quality. As a result of such a determination, when the communication quality of the received data is within a predetermined range (that is, when the result of the determination in ST1700 is No), scheduling is continuously performed by radio resource control section 130, and data transmission is performed. Done.
[0037]
When the measured communication quality is equal to or higher than the predetermined communication quality, that is, when the communication quality of the received data is excessive, the slot that permits the mobile station device that transmitted the data to transmit data is the first slot. It is determined whether or not there is (ST1500). If the result of this determination is that the slot is the first slot, scheduling is subsequently performed by the radio resource control unit 130 and data transmission is performed. On the other hand, if the slot is not the head slot, the slot that permits data transmission to the mobile station device that has transmitted data is changed by one slot to the head slot side of the virtual frame, and the mobile station device that permits data transmission with each slot in the table 142 Is updated (ST1600). As a result, data transmission from a mobile station device that is not greatly affected by interference components from neighboring cells is permitted in a slot on the leading slot side.
[0038]
Also, as a result of the determination in ST 1700, if the measured communication quality is lower than or equal to the predetermined communication quality, that is, if the communication quality of the received data is poor, the mobile station device that transmitted the data is permitted to transmit the data. It is determined whether or not the slot is the last slot (ST1800). If the result of this determination is that the slot is the last slot, scheduling is subsequently performed by the radio resource control unit 130 and data transmission is performed. On the other hand, if the slot is not the last slot, the slot that permits data transmission to the mobile station device that has transmitted the data is changed by one slot to the last slot side of the virtual frame, and each slot in the table 142 and the mobile station device that permits data transmission Is updated (ST1900). As a result, data transmission from a mobile station apparatus that is greatly affected by interference components from neighboring cells is permitted in a slot on the last slot side. Such control is also performed in neighboring cells (cells of base station apparatus 200 and base station apparatus 300 shown in FIG. 1), and thereby, data serving as interference components are transmitted between neighboring cells. Data transmission from the mobile station device to be performed will be permitted in different slots in the virtual frame, and the uplink data in each cell can reduce the interference received by the data transmission of the mobile station device in the neighboring cell. it can.
[0039]
Next, a specific example of the scheduling method according to the present embodiment will be described with reference to FIG.
[0040]
FIG. 4 is a diagram showing an example of the configuration of the virtual frame according to the present embodiment. Here, a virtual frame configuration when the control station apparatus notifies that the virtual frame length is 6 slots (slots 0 to 5) is shown. Also, the base station device 100 communicates with the mobile station device A and the mobile station device B, the base station device 200 communicates with the mobile station device C and the mobile station device D, and the base station device 300 It is assumed that communication is performed with the device E and the mobile station device F.
[0041]
As shown in FIG. 4, slot 0 is assigned to mobile station apparatus A and mobile station apparatus E as a slot for which data transmission is permitted. Similarly, slot 1 is assigned to mobile station apparatus C, and Slot B is assigned to apparatus B, and slot 3 is assigned to mobile station apparatus D and mobile station apparatus F as slots to which data transmission is permitted.
[0042]
Here, for example, when the communication quality of the data transmitted from the mobile station apparatus B to the base station apparatus 100 in the slot 2 is excessive quality, the slot for permitting the mobile station apparatus B to transmit data is the first slot (slot 0). In the table 142, the mobile station device B corresponding to the slot 2 is changed to the mobile station device corresponding to the slot 1 in the table 142. Therefore, when the radio resource control unit 130 performs scheduling, the mobile station device B is read from the table 142 as a mobile station device that permits data transmission in slot 1.
[0043]
Also, for example, when the communication quality of data transmitted from the mobile station apparatus D to the base station apparatus 200 in slot 3 is poor due to interference of data transmitted from the mobile station apparatus F to the base station apparatus 300 in slot 3 In the table 142, the slot in which data transmission is permitted to the mobile station D is changed by one slot toward the last slot (slot 5), and in the table 142, the mobile station D corresponding to the slot 3 is changed to the slot 4 Is changed as a mobile station device corresponding to Therefore, when the radio resource control unit 130 in the base station device 200 performs scheduling, the mobile station device D is read from the table 142 as a mobile station device that permits data transmission in slot 4.
[0044]
As described above, according to the present embodiment, the base station device measures the communication quality of data transmitted from each mobile station device of the communication partner, and determines whether the measured communication quality is within a predetermined range. If the measured communication quality is equal to or more than the predetermined range, the communication quality is determined to be excessive, and a slot that permits data transmission to the mobile station device that transmitted the data is set earlier in the virtual frame. If the measured communication quality is less than or equal to the predetermined range, it is assumed that the interference component from the neighboring cell is large, and the slot that permits the mobile station device that transmitted the data to transmit data is shifted later in the virtual frame. As a result, the transmission efficiency is not extremely reduced, and the timing of data transmission as an interference component to neighboring cells is not simultaneous, thereby reducing signal quality degradation due to the interference component. It is possible to perform favorable communication.
[0045]
(Embodiment 2)
FIG. 5 is a diagram showing an example of a cell configuration according to Embodiment 2 of the present invention. In the figure, cells of base station apparatus 400, base station apparatus 500, base station apparatus 600, and base station apparatus 700 are close to each other. Each cell is divided concentrically into three areas (areas 1 to 3). In the present embodiment, a description will be given assuming that a cell is divided into three concentric circles, but the present invention is not limited to this. Further, base station apparatus 400, base station apparatus 500, base station apparatus 600, and base station apparatus 700 are controlled by a control station apparatus (not shown). This control station device transmits data addressed to each mobile station device to the base station device with which it communicates, and a transmission unit composed of the same number of slots as the number of area divisions of each cell (this embodiment In (2), the length (that is, the number of slots) of this is referred to as a “virtual frame” to the base station apparatus. Thus, base station apparatus 400, base station apparatus 500, base station apparatus 600, and base station apparatus 700 are synchronized with each other.
[0046]
FIG. 6 is a block diagram showing a configuration of base station apparatus 400 according to Embodiment 2. The base station apparatus 400 shown in FIG. 14 includes a radio transmission / reception unit 410, a retransmission control unit 420, a radio resource control unit 430, and a transmission permission slot setting unit 440 including a distance measurement unit 442, a permission slot determination unit 444, and a table 446. Have. Note that base station apparatus 500, base station apparatus 600, and base station apparatus 700 have the same configuration.
[0047]
The wireless transmission / reception unit 410 transmits / receives data via an antenna and performs predetermined wireless processing (encoding, decoding, modulation / demodulation, and the like). Retransmission control section 420 temporarily stores data addressed to each mobile station apparatus transmitted from the control station apparatus, and performs retransmission control. Radio resource control section 430 controls radio transmission / reception section 410 and retransmission control section 420 and performs scheduling. Specifically, when performing scheduling, the radio resource control unit 430 reads from the table 446 the mobile station device to be scheduled (ie, permits data transmission) in each slot, and performs scheduling according to a predetermined algorithm. Do. Furthermore, radio resource control section 430 transmits a transmission permission signal via retransmission control section 420 and radio transmission / reception section 410 to the mobile station apparatus that actually transmits data in each slot.
[0048]
The transmission permission slot setting section 440 includes a distance measurement section 442, a permission slot determination section 444, and a table 446. The virtual frame length notified from the control station apparatus and the virtual frame length notified from the base station apparatus 400 to each mobile station apparatus. Based on the distance, for each slot in the virtual frame, which mobile station device is permitted to transmit data is set. Distance measuring section 442 measures the distance from base station apparatus 400 to each mobile station apparatus. More specifically, the distance measurement unit 442 transmits information to each mobile station apparatus using information such as position information of the mobile station apparatus or a round trip time (Round Trip Time) based on, for example, a GPS (Global Positioning System). Estimate the distance of. The allowed slot determination unit 444 divides the own cell into a plurality of areas according to the number of slots of the virtual frame length notified from the control station device, and determines the slot corresponding to the area where each mobile station device is located. In the present embodiment, since the virtual frame length is described as three slots (slots 0 to 2), allowed slot determination section 444 divides its own cell into three areas and transmits base station apparatus 400 to each mobile station apparatus. The mobile station device determines which area the mobile station device belongs to based on the distance to the mobile station device, and determines a slot corresponding to the area to which the mobile station device belongs.
[0049]
In addition, the permitted slot determination unit 444 holds, for each slot in the virtual frame, slot information indicating whether data transmission is permitted in the own cell. Here, the “slot information indicating whether data transmission is permitted in the own cell” means, for example, that data transmission is permitted in all virtual frames for slot 0 and 1 in 2 for slot 1 This is information indicating that data transmission is permitted in one virtual frame, and data transmission is permitted in one out of three virtual frames for slot 2. In other words, it is information on a cycle in which data transmission is permitted in each slot of each virtual frame. With such slot information, the data transmission cycle can be shifted with respect to neighboring cells for each slot in the virtual frame, and data transmission is permitted in neighboring cells at the timing of slots in which data transmission is permitted in the own cell. There can be situations that are not done. Then, the allowed slot determination unit 444 determines that a slot corresponding to the area to which each mobile station device belongs is a slot to which the mobile station device is allowed to perform data transmission, based on the slot information. And The table 446 holds, for each slot in the virtual frame, a mobile station device that permits data transmission.
[0050]
Next, the operation of setting a transmission permission slot in base station apparatus 400 configured as described above will be described.
[0051]
First, the distance from the base station apparatus 400 to each mobile station apparatus is measured by the distance measurement unit 442 by using information such as the position information of the mobile station apparatus by GPS or the round trip time. The measured distance to each mobile station device is notified to the permitted slot determination unit 444. On the other hand, the allowed slot determination unit 444 is notified of the virtual frame length from the control station device.
[0052]
Then, allowed slot determination section 444 divides the own cell into three areas corresponding to the number of slots of the virtual frame length (three slots 0 to 2 in the present embodiment). This area division is performed according to the distance from the base station apparatus 400. For example, as shown in FIG. 5, the area is divided into an area 1, an area 2, and an area 3 in order from the side closer to the base station apparatus 400. . These areas 1, 2 and 3 respectively correspond to slots 0 to 2 in the virtual frame. Specifically, for example, area 1 corresponds to slot 0, area 2 corresponds to slot 1, and area 3 corresponds to slot 2.
[0053]
Then, according to the distance to each mobile station apparatus notified from distance measuring section 442, allowed slot determining section 444 determines which area each mobile station apparatus belongs to. In addition, the permitted slot determination unit 444 holds, for each virtual frame, slot information that is information on a period in which data transmission is permitted in the own cell. In the present embodiment, slot information indicates that data transmission is permitted in all virtual frames for slot 0, data generation is permitted in one out of two virtual frames for slot 1, and slot 2 Is that data transmission is permitted in one out of three virtual frames. Then, the permitted slot determination unit 444 determines a slot to which data transmission is permitted by the slot information and which corresponds to an area to which each mobile station device belongs, and notifies the table 446 of the determination result. Is done. Based on this notification, the correspondence between each slot in the table 446 and the mobile station device permitting data transmission is updated.
[0054]
As a result, the mobile station device located in area 1 close to base station device 400 is allowed to transmit data in slot 0 of all virtual frames, and in area 2 where the distance from base station device 400 is medium. The mobile station device located in the area 3 is permitted to transmit data in slot 1 of one virtual frame, and the mobile station apparatus located in the area 3 near the cell edge far from the base station apparatus 400 is one in three. Data transmission is allowed in slot 2 of one virtual frame.
[0055]
FIG. 7 is a diagram illustrating slots in which data transmission of mobile station devices located in respective areas in each cell of each base station device is permitted. As shown in the figure, in the first virtual frame (the left virtual frame in the drawing), in the cell of the base station apparatus 400, the data transmission of the mobile station apparatus located in the area 1 (“A1” in the figure) is performed by the slot. 0, data transmission of a mobile station apparatus located in area 2 (“A2” in the figure) is permitted in slot 1, and data transmission of a mobile station apparatus located in area 3 (“A3” in the figure) is performed in the slot. 2 allowed. Similarly, in the cell of the base station apparatus 500, data transmission of the mobile station apparatus located in the area 1 (A1) is permitted in slot 0, and in the cell of the base station apparatus 600, the area 1 (A1) Data transmission of the mobile station device located in area 2 (A2) is permitted in slot 0 and slot 1, respectively.
[0056]
Thereby, for example, when a mobile station device located in area 2 in the cell of base station device 400 is permitted to transmit data, a mobile station device located in area 2 of the cell of adjacent base station device 500 transmits data. Is not permitted, and data transmission is not performed in the cell of the base station device 500, so that there is no influence of interference. Similarly, the mobile station device located in the area 3 near the cell edge in the cell of the base station device 400 is considered to have a large influence as interference on the cells of the neighboring base station devices 500 and 600. When data transmission is permitted to the mobile station apparatus located in No. 3, data transmission is not permitted in the cells of the base station apparatus 500 and the base station apparatus 600, and there is no influence of interference.
[0057]
As described above, according to the present embodiment, for a mobile station device close to a base station device, which has a small influence of interference on a neighboring cell, data transmission is permitted in the same slot of each cell, and Since the mobile station device near the cell edge, which is greatly affected by the interference, does not permit data transmission in the same slot of the neighboring cell, it does not extremely reduce the transmission efficiency and becomes an interference component for the neighboring cell. Data transmission timings are not simultaneous, so that deterioration of signal quality due to interference components can be reduced and good communication can be performed.
[0058]
In this embodiment, the cell is divided into three areas. However, the present invention is not limited to this. The number of areas may be any number. In that case, the number of slots in the virtual frame is changed according to the number of areas.
[0059]
Further, in the present embodiment, as shown in FIG. 7, data transmission of a mobile station device located in area 1 (A1) is permitted only in slot 0, but a mobile station located in area 1 is permitted. Since the apparatus gives little interference to neighboring cells, if there is no mobile station apparatus permitted to transmit data in slot 1 and slot 2, data transmission of the mobile station apparatus located in area 1 is permitted in slot 1 and slot 2. You may do it. Similarly, data transmission of a mobile station device located in area 2 may be permitted not only in slot 1 but also in slot 2.
[0060]
【The invention's effect】
As described above, according to the present invention, it is possible to reduce deterioration in signal quality due to interference components and perform favorable communication.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of a cell configuration according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration of a base station apparatus according to Embodiment 1.
FIG. 3 is a flowchart showing an operation of setting a transmission permission slot according to the first embodiment.
FIG. 4 is a diagram showing an example of a configuration of a virtual frame according to the first embodiment.
FIG. 5 is a diagram showing an example of a cell configuration according to a second embodiment of the present invention.
FIG. 6 is a block diagram showing a configuration of a base station apparatus according to Embodiment 2.
FIG. 7 is a diagram showing an example of a configuration of a virtual frame according to the second embodiment.
FIG. 8 is a diagram for explaining a problem in a conventional cell configuration.
[Explanation of symbols]
110, 410 wireless transceiver
120, 420 retransmission control unit
130, 430 radio resource control unit
140,440 transmission permission slot setting unit
142, 446 tables
144 Communication Quality Comparison Unit
442 Distance measuring unit
444 Permitted slot determination unit

Claims (10)

Setting means for setting a timing for permitting data transmission for each communication partner station according to a communication state in a neighboring cell;
Determining means for determining a communication partner station that actually transmits data at the timing from a communication partner station permitted to transmit data at the same timing among the set timings;
Transmitting means for transmitting a transmission permission signal to the determined communication partner station;
A wireless transmission device comprising: The setting means,
In a virtual frame consisting of a predetermined number of slots, a table holding slots that permit data transmission for each communication partner station,
A communication quality comparison unit that compares the communication quality between the communication partner station and the own station and a predetermined communication quality,
The table is
As a comparison result of the communication quality comparing unit, when the communication quality between the communication partner station and the own station is other than the predetermined communication quality, the slot for permitting data transmission of the communication partner station is changed. The wireless transmission device according to claim 1. The table is
As a result of the comparison by the communication quality comparing section, if the communication quality between the communication partner station and the own station is better than a predetermined communication quality, the slot for permitting data transmission of the communication partner station is set in the leading direction in the virtual frame. 3. The radio transmitting apparatus according to claim 2, wherein the number of times is changed by one slot. The table is
As a result of the comparison by the communication quality comparing unit, if the communication quality between the communication partner station and the own station is inferior to the predetermined communication quality, the slot for permitting data transmission of the communication partner station is set to the final direction in the virtual frame. 3. The radio transmitting apparatus according to claim 2, wherein the number of times is changed by one slot. The setting means,
In a virtual frame consisting of slots corresponding to areas into which the own cell has been divided according to the distance from the own station, a table holding slots that permit data transmission for each communication partner station,
A distance measuring unit for measuring a distance between the communication partner station and the own station;
Permitted slot for determining a slot for which data transmission is permitted for each communication partner station based on the measured distance and slot information indicating whether data transmission is permitted in the own cell for each slot in the virtual frame. A determination unit;
The table is
The wireless transmission device according to claim 1, wherein the wireless transmission device is updated based on a determination result of the permission slot determination unit. The slot information includes:
6. The wireless transmission apparatus according to claim 5, wherein a slot corresponding to an area closer to the own station indicates that data transmission is permitted more frequently. The slot information includes:
6. The slot according to claim 5, wherein a slot corresponding to an area far from the own station and for which data transmission is not allowed in the same slot of a neighboring cell indicates that data transmission is allowed in the own cell. Wireless transmission device. The setting means,
2. The radio transmission apparatus according to claim 1, wherein a timing for permitting data transmission in an uplink is set according to a communication state in a neighboring cell. A base station device comprising the wireless transmission device according to claim 1. Setting the timing of permitting data transmission for each communication partner station according to the communication status in the neighboring cell;
Determining a communication partner station to actually transmit data at the timing from a communication partner station permitted to transmit data at the same timing among the set timings;
Transmitting a transmission permission signal to the determined communication partner station;
A scheduling method, comprising:

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