JP2016111431A - Radio communication system, base station device, and terminal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication system, a base station device, and a terminal device that can appropriately schedule radio resources.SOLUTION: A radio communication system comprises a base station device and a terminal device for communicating with the base station device. The radio communication system comprises: a storage unit for storing interference information in a certain area per frequency band in a frequency band used in the radio communication system; and a scheduling unit for scheduling radio resources on the basis of the interference information stored in the storage unit.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a radio communication system, a base station apparatus, and a terminal apparatus.

Currently, various services such as mobile communication service, satellite communication service, weather radar, GPS (Global Positioning System), digital terrestrial broadcasting, and wireless communication service are implemented in various frequency bands (also referred to as “bands”). ing. Of the frequency bands, the 5 GHz band is used as a license-free frequency band (also referred to as “unlicensed band”) for wireless communication services such as WiFi (registered trademark) services.
The LTE (Long Term Evolution) using an unlicensed band has been studied in 3GPP (3rd Generation Partnership Project) targeting the standardized standard after Release 13.
However, since the unlicensed band is a frequency band that does not require a license, various services compete and there is a concern about mutual interference in these services.
For example, the technology described in Patent Document 1 is based on a Bluetooth (registered trademark) or WiFi (registered trademark) with respect to LTE in a terminal device equipped with at least one of Bluetooth (registered trademark) or WiFi (registered trademark) and LTE. It is determined whether interference causes interference and reports to the network side to reduce interference or prevent interference.

Special table 2014-513447 gazette

However, in the technique described in Patent Document 1, since it is necessary for each terminal device to measure interference, and only interference information about interference that can be measured by the terminal device can be obtained, the reliability of the measured interference information can be obtained. However, when the base station apparatus performs scheduling of radio resources based on such interference information with low reliability, there is a problem in that the throughput of the entire base station apparatus is reduced.
As described above, there has been a problem that radio resources cannot be appropriately scheduled.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a radio communication system, a base station apparatus, and a terminal apparatus capable of appropriately scheduling radio resources.

  (1) The present invention has been made to solve the above problems, and a first aspect of the present invention is a radio communication system including a base station apparatus and a terminal apparatus that communicates with the base station apparatus. In the frequency band used in the wireless communication system, for each frequency band, based on the interference information stored in the storage unit, the storage unit that stores the interference information in a certain area, And a scheduling unit that performs scheduling of radio resources.

  (2) Moreover, the 2nd aspect of this invention is a base station apparatus which communicates with a terminal device, Comprising: The measurement part which measures interference information, The said interference information measured by the said measurement part at least, and known interference A storage unit that stores at least one piece of interference information including information and a statistical value of interference information received from each terminal device when receiving interference information from the terminal device; and the interference information stored by the storage unit And a scheduling unit that performs radio resource scheduling based on the base station apparatus.

  (3) Moreover, the 3rd aspect of this invention is a terminal device which communicates with a base station apparatus, Comprising: The measurement part which measures 1st interference information, and the said 1st interference information to the said base station apparatus And a communication unit that communicates with the base station apparatus using radio resources scheduled by the base station apparatus based on the first interference information and the second interference information measured by the base station apparatus. And a terminal device.

  According to the present invention, radio resources can be appropriately scheduled.

It is the schematic which shows an example of a structure of the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a schematic block diagram which shows an example of a function structure of the terminal device which concerns on 1st Embodiment. It is a schematic block diagram which shows an example of a function structure of the base station apparatus which concerns on 1st Embodiment. It is the schematic which shows an example of the interference information which the database which concerns on 1st Embodiment memorize | stores. It is the schematic which shows an example of the interference information which the database which concerns on 1st Embodiment memorize | stores. It is a flowchart which shows an example of the scheduling process of the radio | wireless resource which concerns on 1st Embodiment. It is the schematic which shows an example of the interference information which the database which concerns on 2nd Embodiment memorize | stores. It is the schematic which shows an example of the interference information which the database which concerns on 2nd Embodiment memorize | stores. 6 is a flowchart illustrating an example of radio resource scheduling processing according to the second embodiment. It is the schematic which shows an example of the interference information which the database which concerns on 3rd Embodiment memorize | stores. It is the schematic which shows an example of the interference information which the database which concerns on 3rd Embodiment memorize | stores. 12 is a flowchart illustrating an example of radio resource scheduling processing according to the third embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
(First embodiment)
First, a first embodiment of the present invention will be described.

FIG. 1 is a schematic diagram illustrating an example of a configuration of a wireless communication system S1 according to the first embodiment of the present invention.
The radio communication system S1 includes a base station device BS1, a base station device BS2, a base station device BS3, a terminal device UE1, a terminal device UE2, and a database DB1. It is assumed that the wireless communication system S1 receives interference due to interference waves from the interference station IF1 and the interference station IF2.
For example, the terminal device UE1 and the terminal device UE2 are a mobile phone terminal, a multi-function mobile terminal (smart phone), a tablet PC, a notebook PC, or the like having a data communication function and a voice communication function. The database DB1 is a database that stores information regarding interference.
In the illustrated example, the database DB1 exists in the wireless communication system S1, and the database DB1 is connected to each base station device such as the base station device BS1, the base station device BS2, and the base station device BS3. The database DB1 may be configured to be included in at least one of the base station devices.

  Each of the base station device BS1, the base station device BS2, and the base station device BS3 is connected by a wired or wireless connection with the database DB1 and each of the link L1, the link L2, and the link L3. Also, each of the base station device BS1, the base station device BS2, and the base station device BS3 are interconnected by, for example, an X2 interface (not shown). In addition, each of the base station device BS1, the base station device BS2, and the base station device BS3 is connected to a core network (not shown). Each of the base station device BS1, the base station device BS2, and the base station device BS3 forms a cell CE1, a cell CE2, and a cell CE3 as communication ranges that can communicate with the own device. In the illustrated example, each of the cell CE1, the cell CE2, and the cell CE3 is an example when the base station apparatuses are arranged so that a part of the cells overlap each other. For example, in the cell CE1, there is a terminal device UE1 that can communicate with the base station device BS1, and the base station device BS1 and the terminal device UE1 communicate with each other. Further, for example, in the cell CE2, there is a terminal device UE2 that can communicate with the base station device BS2, and the base station device BS2 and the terminal device UE2 communicate with each other.

  Here, in the vicinity of the base station apparatus BS1, there is an interference station IF1 that interferes with communication of the base station apparatus BS1 such as communication between the base station apparatus BS1 and the terminal apparatus UE1. For example, in the cell CE1 formed by the base station device BS1, if the interference station IF1 is a terrestrial digital broadcast station that performs terrestrial digital broadcasting, it is possible to receive an interference wave from terrestrial digital broadcasting as interference in the 700 MHz band from the interference station IF1. Assume that there is. That is, it is assumed that the terminal apparatus UE1 can perform data communication with the base station apparatus BS1 and can receive an interference wave such as a 700 MHz band terrestrial digital broadcast wave from the terrestrial digital broadcast station.

  Further, in the vicinity of the base station device BS2 and the base station device BS3, interference that interferes with communication of the base station device BS2 such as communication between the base station device BS2 and the terminal device UE2 and communication of the base station device BS3. Station IF2 exists. For example, in the CE2 formed by the base station device BS2 and the cell CE3 formed by the base station device BS3, if the interference station IF2 is a weather radar, interference waves from the weather radar are generated as interference in the 5.2 GHz band from the interference station IF2. Assume that it is detectable. That is, it is assumed that the terminal apparatus UE2 performs voice communication with the base station apparatus BS2 and receives an interference wave such as a 5.2 GHz band satellite signal from the weather radar.

FIG. 2 is a schematic block diagram illustrating an example of a functional configuration of the terminal device UE1 according to the present embodiment.
The terminal device UE1 includes an antenna 1011, 1012, 1013, 1014, 1015, an LTE transmission unit A1021, an LTE transmission unit B1022, an LTE reception unit A1031, an LTE reception unit B1032, an interference wave reception unit 104, and a control unit. 105. The control unit 105 includes a broadcast channel detection unit 1051, an interference acquisition unit 1052, and an interference information report unit 1053.

The antenna 1011 is an antenna used when the LTE transmission unit A1021 communicates with the base station apparatus BS1 or another terminal apparatus. The antenna 1012 is an antenna used when the LTE transmission unit B1022 communicates with the base station apparatus BS1 or another terminal apparatus.
The antenna 1013 is an antenna used when the LTE receiving unit A1031 communicates with the base station apparatus BS1 or another terminal apparatus. The antenna 1014 is an antenna used when the LTE receiving unit B 1032 communicates with the base station apparatus BS1 or another terminal apparatus.
The antenna 1015 is an antenna for the interference wave receiving unit 104 to receive an interference wave.

  The LTE transmission unit A1021 and the LTE transmission unit B1022 are LTE transmission units for the frequency band A and the frequency band B, respectively. That is, the frequency bands used by the LTE transmission unit A1021 and the LTE transmission unit B1022 are different. Here, the frequency band A and the frequency band B are frequency bands that can be used by the terminal device UE1 defined in the wireless communication system. For example, the frequency band A is a 700 MHz band, and the frequency band B is a 5.2 GHz band.

  LTE receiver A 1031 and LTE receiver B 1032 are LTE receivers for frequency band A and frequency band B, respectively. That is, the frequency bands used by the LTE receiving unit A 1031 and the LTE receiving unit B 1032 are different. Further, the LTE receiving unit A1031 is an LTE receiving unit that performs communication using the frequency band A corresponding to the LTE transmitting unit A1021, and the LTE receiving unit B1032 performs communication using the frequency band B corresponding to the LTE transmitting unit B1022. It is an LTE receiving unit that performs.

  In this embodiment, each of the LTE transmission unit A1021 and the LTE transmission unit B1022 is illustrated separately, but what can be shared in the LTE transmission unit A1021 and the LTE transmission unit B1022 is a configuration to be shared. May be. In the present embodiment, the LTE receiving unit A 1031 and the LTE receiving unit B 1032 are separately illustrated. However, what can be shared in the LTE receiving unit A 1031 and the LTE receiving unit B 1032 is a configuration to be shared. May be.

  The interference wave receiving unit 104 is a receiving unit that can receive a communication wave of another system as an interference wave. For example, the interference wave receiving unit 104 is a terrestrial digital broadcast receiving unit, and is a receiving unit capable of receiving all broadcast channels. The interference wave receiving unit 104 is an example of a terminal device equipped with a terrestrial digital broadcast receiver, and other wireless communication such as WiFi (registered trademark), Bluetooth (registered trademark), a radio broadcast receiver, and a satellite communication receiver. It may be the case where the system is installed, and is the same as the case where the terrestrial digital broadcast receiver is installed.

The control unit 105 performs control related to communication of the terminal apparatus UE1 and reception of interference waves (terrestrial digital broadcast waves) such as processing for received data, processing for transmission data, and carrier frequency control of each LTE transmission / reception unit. Specifically, it is as follows.
The broadcast channel detecting unit 1051 detects a broadcast channel that can be received at the position of the terminal device UE1 by performing an all-channel search in the interference wave receiving unit 104.
The interference acquisition unit 1052 acquires all channels detected by the broadcast channel in the broadcast channel detection unit 1051 or a frequency band corresponding to the channel. In addition, the interference acquisition unit 1052 may acquire only a channel corresponding to a frequency band used in LTE, a broadcast channel in a frequency band corresponding to the channel, or a frequency band corresponding to the broadcast channel. .
The interference information reporting unit 1053 reports (transmits) the broadcast channel or frequency band information acquired by the interference acquisition unit 1052 as interference information to the base station apparatus BS1 through the LTE transmission unit A1021 and the LTE transmission unit B1022.

  Note that the configuration of the terminal device UE2 is the same as that of the terminal device UE1, and thus the description thereof is omitted.

FIG. 3 is a schematic block diagram illustrating an example of a functional configuration of the base station device BS1 according to the present embodiment.
The base station apparatus BS1 includes antennas 2011, 2012, 2013, 2014, 2015, an LTE transmission unit A2021, an LTE transmission unit B2022, an LTE reception unit A2031, an LTE reception unit B2032, an interference wave reception unit 204, and a control. Unit 205. The control unit 205 includes an interference information reception unit 2051, an interference wave detection unit 2052, an interference information control unit 206, and a scheduling processing unit 2055. The interference information control unit 206 includes an interference information processing unit 2053 and an interference information storage unit 2054.

The antenna 2011 is an antenna used when the LTE transmission unit A2021 communicates with the terminal device UE1 or another terminal device. The antenna 2012 is an antenna used when the LTE transmission unit B2022 communicates with the terminal device UE1 or another terminal device.
The antenna 2013 is an antenna used when the LTE receiving unit A2031 communicates with the terminal device UE1 or another terminal device. The antenna 2014 is an antenna used when the LTE receiving unit B 2032 communicates with the terminal device UE1 or another terminal device.
The antenna 2015 is an antenna for the interference wave receiving unit 204 to receive the interference wave.

  The LTE transmission unit A 2021 and the LTE transmission unit B 2022 are LTE transmission units for the frequency band A and the frequency band B, respectively. That is, the frequency bands used by the LTE transmission unit A2021 and the LTE transmission unit B2022 are different. Here, the frequency band A and the frequency band B are frequency bands that can be used by the base station apparatus BS1 defined in the wireless communication system. For example, the frequency band A is a 700 MHz band, and the frequency band B is a 5.2 GHz band.

  The LTE receiving unit A 2031 and the LTE receiving unit B 2032 are LTE receiving units for the frequency band A and the frequency band B, respectively. That is, the frequency bands used by the LTE receiver A2031 and the LTE receiver B2032 are different. The LTE receiving unit A2031 is an LTE receiving unit that performs communication using the frequency band A corresponding to the LTE transmitting unit A2021, and the LTE receiving unit B2032 performs communication using the frequency band B corresponding to the LTE transmitting unit B2022. It is an LTE receiving unit that performs.

  In this embodiment, each of the LTE transmission unit A 2021 and the LTE transmission unit B 2022 is illustrated separately, but what can be shared in the LTE transmission unit A 2021 and the LTE transmission unit B 2022 is a configuration to be shared. May be. In this embodiment, the LTE receiving unit A2031 and the LTE receiving unit B2032 are separately illustrated. However, what can be shared in the LTE receiving unit A2031 and the LTE receiving unit B2032 is a configuration to be shared. May be.

  The interference wave receiving unit 204 is a receiving unit that can receive a communication wave of another system as an interference wave. For example, the interference wave receiving unit 204 is a receiving unit that can receive a radar signal such as a weather radar that is a satellite signal as an interference wave.

The control unit 205 performs control related to communication of the base station apparatus BS1 and reception of interference waves, such as processing for reception data, processing for transmission data, and carrier frequency control of each LTE transmission / reception unit. Specifically, it is as follows.
The interference information receiving unit 2051 receives the interference information transmitted (reported) from each terminal device, and outputs it to the interference information processing unit 2053.
The interference wave detection unit 2052 detects the frequency band of the radar signal received by the interference wave reception unit 204. The interference wave detection unit 2052 outputs the detected frequency band of the radar signal to the interference information processing unit 2053.

The interference information processing unit 2053 statistically analyzes the interference information of each terminal device input from the interference information receiving unit 2051, and calculates the frequency band of the interference wave that causes interference such as digital terrestrial broadcasting. For example, when the number of reports of each interference frequency band reported from each terminal apparatus exceeds a certain threshold value α, the frequency band is determined to have interference. In this case, for example, the number of reports is smoothed over time. The interference information processing unit 2053 causes the interference information storage unit 2054 to store the calculated frequency band of the interference wave and the frequency band of the radar signal input from the interference wave detection unit 2052 as interference frequency band information.
The interference information storage unit 2054 stores interference information such as interference frequency band information.
The scheduling processing unit 2055 reads the interference information stored in the interference information storage unit 2054, and performs scheduling of component carriers and radio resources based on the read interference information.

  The interference information storage unit 2054 may be configured in the database DB1. Thereby, the interference information of each base station apparatus can be integrated in database DB1, and it can be made easy to cooperate with respect to interference in each base station apparatus. Further, the database DB1 may be configured to include the interference information control unit 206 including the interference information processing unit 2053 and the interference information storage unit 2054. In this case, the interference information of each terminal device and the interference information detected by the interference wave detection unit 2052 of each base station device may be reported to the database DB1. Thereby, the structure of each base station apparatus can be simplified.

  Note that the configurations of the base station device BS2 and the base station device BS3 are the same as the configuration of the base station device BS1, and thus the description thereof is omitted.

FIG. 4 is a schematic diagram illustrating an example of interference information stored in the database DB1 according to the present embodiment.
The interference information table T11 includes two-dimensional rows and columns in which information on presence / absence of interference is stored so as to correspond to IDs of base station apparatuses and frequency bands that can be allocated by the wireless communication system (LTE system). It is a tabular table.
For example, the first row of the table T11 is a base station ID “1” that is an identifier of the base station apparatus, and a frequency band 700 MHz “1”, 720 MHz “0”,..., 5200 MHz “0”, 5220 MHz “0”. "5240 MHz" 0 ". For example, the second row of the table T11 is the base station ID “2”, and the frequency band 700 MHz “0”, 720 MHz “0”,..., 5200 MHz “1”, 5220 MHz “1”, 5240 MHz “0”. It is. The third line is a base station ID “3”, and a frequency band 700 MHz “0”, 720 MHz “0”,..., 5200 MHz “1”, 5220 MHz “1”, 5240 MHz “0”.
That is, in the example of the first row, “1” is stored in the 700 MHz frequency band (frequency band, frequency band) in the base station apparatus whose base station ID is “1”. This indicates that an interference wave exists.

  The tables T12 and T13 may be stored as an interference information table in which time information such as a time zone is associated with an interference information table such as the table T11 as illustrated.

FIG. 5 is a schematic diagram illustrating an example of interference information stored in the database (interference information storage unit 2054 of each base station device) according to the present embodiment.
The table T21 is a table in a tabular format including two-dimensional rows and columns in which information on the presence or absence of interference is stored so as to correspond to frequency bands that can be allocated by the wireless communication system (LTE system).
For example, the first row of the table T21 includes frequency bands 700 MHz “0”, 720 MHz “0”,..., 5200 MHz “1”, 5220 MHz “1”, and 5240 MHz “0”.
That is, in the example of the first row, “1” is stored in each of the 5200 MHz and 5220 MHz frequency bands (frequency band, frequency band) in the base station apparatus BS1, so that there is an interference wave in the frequency band. It represents that.

  The table T22 may be stored as a table of interference information in which time information such as a time zone is associated with a table of interference information like the table T21 as illustrated.

FIG. 6 is a flowchart showing an example of radio resource scheduling processing according to the present embodiment.
In step ST101, the scheduling processing unit 2055 of the base station apparatus BS1 reads out and acquires interference information from the database DB1 (interference information storage unit 2054).
In Step ST102, the scheduling processing unit 2055 refers to the read interference information and determines whether or not there is interference in the frequency band used in the component carrier (CCn) allocated to the terminal device UE1. When interference exists in the frequency band used by the component carrier (CCn) assigned (scheduled) to the terminal apparatus UE1 (step ST102; YES), the scheduling processing unit 2055 performs the process of step ST103. On the other hand, when there is no interference in the frequency band used in the component carrier (CCn) assigned to the terminal device UE1 (step ST102; NO), the scheduling processing unit 2055 performs the process of step ST108.

  In Step ST103, the scheduling processing unit 2055 determines whether or not the component carrier (CCn) assigned to the terminal device UE1 corresponds to FDD (frequency division multiplexing). When the component carrier (CCn) assigned to the terminal device UE1 corresponds to FDD (frequency division multiplexing) (step ST103; YES), the scheduling processing unit 2055 performs the process of step ST104. On the other hand, when the component carrier (CCn) assigned to the terminal device UE1 does not correspond to FDD (frequency division multiplexing) (step ST103; NO), the scheduling processing unit 2055 performs the process of step ST107.

  In Step ST104, the scheduling processing unit 2055 refers to the interference information acquired from the database DB1 (interference information storage unit 2054), and sets the frequency band of the component carrier (CCn) to be allocated (scheduled) to the downlink of the terminal device UE1. It is determined whether there is no interference. When there is no interference in the frequency band of the component carrier (CCn) assigned (scheduled) to the downlink of the terminal device UE1 (step ST104; YES), the scheduling processing unit 2055 performs the process of step ST109. On the other hand, when interference exists in the frequency band of the component carrier (CCn) assigned (scheduled) to the downlink of the terminal device UE1 (step ST104; NO), the scheduling processing unit 2055 performs the process of step ST105.

  In Step ST105, the scheduling processing unit 2055 refers to the interference information acquired from the database DB1 (interference information storage unit 2054), and sets the frequency band of the component carrier (CCn) to be allocated (scheduled) to the uplink of the terminal device UE1. It is determined whether there is no interference. When there is no interference in the frequency band of the component carrier (CCn) assigned (scheduled) to the uplink of the terminal apparatus UE1 (step ST105; YES), the scheduling processing unit 2055 performs the process of step ST106. On the other hand, when interference exists in the frequency band of the component carrier (CCn) assigned (scheduled) to the uplink of the terminal apparatus UE1 (step ST105; NO), the scheduling processing unit 2055 performs the process of step ST107.

In Step ST106, the scheduling processing unit 2055 determines to use the component carrier (CCn) as an uplink dedicated Scell.
In Step ST107, the scheduling processing unit 2055 determines that the component carrier (CCn) is an interference component carrier and does not schedule the component carrier (CCn).
In Step ST108, the scheduling processing unit 2055 determines that the component carrier (CCn) can be used in one or both of the uplink and the downlink, and determines to use the component carrier (CCn) as the Pcell or Scell.
In Step ST109, the scheduling processing unit 2055 determines to use the component carrier (CCn) as a downlink dedicated Scell.

In this way, based on the intended use determined by the processing from step ST101 to step ST109 (any one of step ST106 to step ST109), the scheduling processing unit 2055 provides the component carrier (CCn) and the terminal device UE1. Schedule radio resources.
In addition, in FDD, when adding as downlink dedicated Scell, the scheduling process part 2055 preferentially schedules the component carrier (CCn) (step ST109) determined to be used as downlink dedicated Scell. Also good.
In addition, in FDD, when adding as uplink dedicated Scell, the scheduling process part 2055 preferentially schedules the component carrier (CCn) (step ST106) determined to be used as uplink dedicated Scell. Also good.
As described above, by scheduling radio resources based on highly reliable interference information held by each base station apparatus, it is possible to prevent the throughput of each base station apparatus from being lowered. Further, in LTE CC using FDD, it is possible to effectively use radio resources even when there is interference in the uplink or downlink frequency band, so that the throughput of the entire radio communication system can be improved.

  In the above embodiment, interference information is held for each base station apparatus, but interference information may be held in units of regions. For example, interference information may be held for each base station device group ID by giving a base station device group ID in which a plurality of base station devices are grouped. In this case, the interference information can be acquired from the adjacent base station apparatus, but when the wireless communication system S1 has the database DB1, the interference information does not have to be acquired from the adjacent base station apparatus.

Thus, according to the present embodiment, the radio communication system S1 is a radio communication system S1 including the base station device BS1 and the terminal device UE1 that communicates with the base station device BS1, and is the radio communication system S1. In a frequency band to be used, a storage unit (database DB1 or interference information storage unit 2054) that stores interference information within a certain area and a storage unit (database DB1 or interference information storage unit 2054) for each frequency band. A scheduling unit (scheduling processing unit 2055) that schedules radio resources based on the stored interference information.
Thereby, a radio | wireless resource can be scheduled appropriately.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.
First, the configuration of the terminal device UE1 will be described.
Since the configuration of the terminal device UE1 is the same as the configuration of the terminal device UE1 according to the first embodiment, the difference between the terminal device UE1 according to the first embodiment and the terminal device UE1 according to the second embodiment The explanation will be focused on.

The interference acquisition unit 1052 acquires all channels detected in the broadcast channel or frequency bands corresponding to the channels and the magnitude of the interference level. Here, the interference level is represented by a predetermined step value, for example, a value of 10 steps. For example, if the interference level is −100 dBm, the interference level is “3” and the interference level is Is −30 dBm or more, it is expressed as an interference level “10” or the like.
The acquired all channels or the frequency band corresponding to all the channels corresponds to the channel corresponding to the frequency band used in LTE, all the broadcast channels in the frequency band corresponding to the channel, or all the channels. You may make it acquire a frequency band.
The interference information reporting unit 1053 reports all channels detected by the broadcast channel acquired by the interference acquisition unit 1052 or frequency bands corresponding to the channels and the magnitude of the interference level to the base station apparatus BS1 as interference information.

Next, the configuration of the base station apparatus BS1 will be described.
Since the configuration of the base station device BS1 is the same as the configuration of the base station device BS1 according to the first embodiment, the base station device BS1 according to the first embodiment and the base station device BS1 according to the second embodiment. The explanation will focus on the different parts.

The interference wave detection unit 2052 detects the frequency band of the radar signal received by the interference wave reception unit 204 and the magnitude of the interference level. Here, the interference level is represented by a predetermined step value, for example, a value of 10 steps. For example, if the interference level is −100 dBm, the interference level is “3” and the interference level is Is −30 dBm or more, it is expressed as an interference level “10” or the like.
The interference information processing unit 2053 statistically analyzes the interference information received from each terminal device by the interference information receiving unit 2051, and calculates a frequency band causing interference such as terrestrial digital broadcasting and the magnitude of the interference level. For example, the average value or median value of the interference levels in each frequency band reported from each terminal device is determined as the interference value in that frequency band. The interference information processing unit 2053 then uses the calculated frequency band and the level of interference level, the frequency band of the radar signal detected by the interference wave detection unit 2052 and the level of the interference level as interference information, as an interference information storage unit 2054. Remember me.

FIG. 7 is a schematic diagram illustrating an example of interference information stored in the database DB1 according to the present embodiment.
In the example of the table T11 illustrated in FIG. 4, the example in which the presence / absence of interference for each frequency band is represented by “1” and “0” has been described. However, in the example illustrated in the table T16 of FIG. For example, evaluation values such as evaluation values evaluated in 11 stages from “0” indicating that the influence of interference is small to “10” indicating that the influence of interference is large are frequency bands. The stored interference information is stored.

FIG. 8 is a schematic diagram illustrating an example of interference information stored in the database (interference information storage unit 2054 of each base station device) according to the present embodiment.
In the example of the table T21 illustrated in FIG. 5, the example in which the presence / absence of interference for each frequency band is represented by “1” and “0” has been described. However, as illustrated in the table T24 of FIG. For example, evaluation values such as evaluation values evaluated in 11 stages from “0” indicating that the influence of interference is small to “10” indicating that the influence of interference is large are frequency bands. The stored interference information is stored.

FIG. 9 is a flowchart showing an example of radio resource scheduling processing according to the present embodiment.
In step ST201, the scheduling processing unit 2055 of the base station apparatus BS1 reads out and acquires interference information from the database DB1 (interference information storage unit 2054).
In Step ST202, the scheduling processing unit 2055 refers to the read interference information and determines whether or not the interference level of the frequency band used in the component carrier (CCn) allocated to the terminal device UE1 is “1” or less. . When the interference level of the frequency band used in the component carrier (CCn) assigned (scheduled) to the terminal device UE1 is “1” or less (step ST202; YES), the scheduling processing unit 2055 performs the process of step ST205. On the other hand, when the interference level of the frequency band used by the component carrier (CCn) allocated to the terminal device UE1 is not “1” or less (step ST202; NO), the scheduling processing unit 2055 performs the process of step ST203.

  In Step ST203, the scheduling processing unit 2055 refers to the read interference information and determines whether or not the interference level of the frequency band used in the component carrier (CCn) allocated to the terminal device UE1 is “5” or less. . When the interference level of the frequency band used by the component carrier (CCn) assigned (scheduled) to the terminal device UE1 is “5” or less (step ST203; YES), the scheduling processing unit 2055 performs the process of step ST206. On the other hand, when the interference level of the frequency band used by the component carrier (CCn) assigned to the terminal device UE1 is not “5” or less (step ST203; NO), the scheduling processing unit 2055 performs the process of step ST204.

In Step ST204, the scheduling processing unit 2055 determines that the component carrier (CCn) is an interference component carrier and does not schedule the component carrier (CCn).
In step ST205, the scheduling processing unit 2055 assigns the component carrier (CCn) from communication with high QoS (Quality of Service), for example, communication such as control signal or real-time signal, to communication with low QoS, for example, best effort communication. To be used for any communication.
In Step ST206, the scheduling processing unit 2055 determines to use the component carrier (CCn) only as communication with low QoS.

As described above, based on the usage (determined from any of step ST204 to step ST206) determined by the process from step ST201 to step ST206, the scheduling processing unit 2055 determines the component carrier (CCn) and the terminal device UE1. Schedule radio resources.
In this embodiment, the component carrier (CCn) used for communication with high QoS, the component carrier (CCn) used for communication with low QoS, and the interference component carrier (CCn) according to the magnitude of the interference level. Although the component carrier (CCn) not to be used has been determined, the usage of the component carrier (CCn) may be further classified according to QoS.

In the case of a component carrier (CCn) in FDD, the higher interference level between the uplink interference level and the downlink interference level may be set as the interference level of the component carrier (CCn).
The radio resource scheduling process according to the first embodiment may be combined with the radio resource scheduling process according to the present embodiment. For example, when the interference level of the upstream frequency band of the component carrier (CCn) in FDD is as large as 8, and the interference level of the downstream frequency band of the component carrier (CCn) in FDD is 4 and medium, The component carrier (CCn) is a downlink-dedicated Scell and is used only for communication with lower QoS.
As described above, by scheduling radio resources based on highly reliable interference information held by each base station apparatus, it is possible to prevent the throughput of each base station apparatus from being lowered. In addition, even when there is moderate interference in the LTE component carrier (CCn), it is possible to effectively use radio resources, such as using for communication with low QoS, thereby improving the throughput of the entire radio communication system. Can do.

Radio resource scheduling may be performed according to the magnitude of the interference level and the radio quality state of the terminal device. For example, for a terminal device with low radio quality, for example, a terminal device that exists at the edge of a cell of a base station device, a component carrier (CCn) having an interference level “1” or lower is always used regardless of QoS. You may do it.
Note that the component carrier (CCn) determined not to be used as the interference component carrier (CCn) may be scheduled to be usable by a terminal device having high radio quality if the interference level is 6 to 9.

Thus, according to the present embodiment, the radio communication system S1 is a radio communication system S1 including the base station device BS1 and the terminal device UE1 that communicates with the base station device BS1, and is the radio communication system S1. In a frequency band to be used, a storage unit (database DB1 or interference information storage unit 2054) that stores interference information within a certain area and a storage unit (database DB1 or interference information storage unit 2054) for each frequency band. A scheduling unit (scheduling processing unit 2055) that schedules radio resources based on the stored interference information.
Thereby, a radio | wireless resource can be scheduled appropriately.

(Third embodiment)
Next, a third embodiment of the present invention will be described.
First, the configuration of the terminal device UE1 will be described.
The configuration of the terminal device UE1 is different from the configuration of the terminal device UE1 according to the first embodiment in that it includes the position detection unit 106, but the other configurations are the same, and thus the illustration and description are omitted. The description will focus on the differences between the terminal device UE1 according to the embodiment and the terminal device UE1 according to the third embodiment.

The position detection unit 106 measures the position of the terminal device UE1. The position detection unit 106 measures the latitude, longitude, etc. by GPS, for example, and detects position information.
The interference information report unit 1053 transmits to the base station apparatus BS1 as interference information all channels detected by the broadcast channel acquired by the interference acquisition unit 1052 or frequency bands corresponding to the channels and the position information detected by the position detection unit 106. Report.

Next, the configuration of the base station apparatus BS1 will be described.
Since the configuration of the base station device BS1 is the same as the configuration of the base station device BS1 according to the first embodiment, the base station device BS1 according to the first embodiment and the base station device BS1 according to the third embodiment. The explanation will focus on the different parts.

The interference information reception unit 2051 receives interference information reported from the terminal device UE1.
The interference information processing unit 2053 statistically analyzes the interference information reported from each terminal device for each position in the cell based on the position information received from each terminal device by the interference information receiving unit 2051, and A frequency band that causes interference such as broadcasting is calculated. Then, the interference information processing unit 2053 causes the interference information storage unit 2054 to store the calculated frequency band and the frequency band of the radar signal detected by the interference wave detection unit 2052 as interference information. Note that the interference information detected by the interference wave detection unit 2052 is determined as interference at all positions in the cell.

FIG. 10 is a schematic diagram illustrating an example of interference information stored in the database DB1 according to the present embodiment.
Tables T14 and T15 are stored as interference information tables in which position information acquired by GPS, for example, is associated with a table of interference information like the table T11 shown in FIG.

FIG. 11 is a schematic diagram illustrating an example of interference information stored in the database (interference information storage unit 2054 of each base station device) according to the present embodiment.
The table T23 is stored as an interference information table in which, for example, position information acquired by GPS is associated with an interference information table like the table T21 illustrated in FIG.

FIG. 12 is a flowchart showing an example of radio resource scheduling processing according to the present embodiment.
In step ST301, communication connection is started between the base station apparatus BS1 and the terminal apparatus UE1.
In step ST302, the position detection unit 106 of the terminal apparatus UE1 periodically acquires a position such as latitude and longitude, detects position information, and reports the position information to the base station apparatus BS1 as interference information. The interference information receiving unit 2051 of the base station device BS1 acquires the location information reported from the terminal device UE1.

In step ST303, the scheduling processing unit 2055 of the base station apparatus BS1 uses the database DB1 (base station apparatus BS1 It is read from the interference information storage unit 2054) and acquired.
In Step ST304, the scheduling processing unit 2055 of the base station apparatus BS1 performs one of the radio resource scheduling process according to the first embodiment shown in FIG. 6 and the radio resource scheduling process according to the second embodiment shown in FIG. Alternatively, the usage of the component carrier (CCn) is determined by both.
In Step ST305, the scheduling processing unit 2055 of the base station apparatus BS1 performs scheduling for the terminal apparatus UE1 according to the determined usage of the component carrier (CCn).

In addition, when the position information is acquired from the terminal device UE1 by storing in advance the usage of the component carrier (CCn) corresponding to the position information in the interference information storage unit 2054 or the database DB1, the component carrier stored in advance is stored. You may schedule a radio | wireless resource according to the use use of (CCn).
In the present embodiment, the interference of systems other than the LTE system is databased, but may be databased including the interference of neighboring LTE cells. For example, as a neighboring cell (here, a spot cell in a macro cell), it is possible to avoid spot cell interference in which a macro cell such as a CSG cell defined in the 3GPP standard cannot be grasped. As an example of a method for detecting adjacent LTE cell interference, it is determined that there is interference when RSRQ (reception quality) is low and RSRP (reception level) is high. Of course, there is a possibility that it is not interference of adjacent LTE cells but spot interference such as WiFi, but it can be determined that it is at least an interference band.

In the first to third embodiments, the interference information stores the statistical value reported from each terminal device and the interference measured by each base station device. Interference measured by the apparatus and interference information known in the area may be stored in advance.
In addition, although the LTE system was demonstrated from the said 1st Embodiment to 3rd Embodiment, it is not limited to a LTE system, Even if each embodiment of this invention is applied with respect to another radio | wireless communications system. Good.

Thus, according to the present embodiment, the radio communication system S1 is a radio communication system S1 including the base station device BS1 and the terminal device UE1 that communicates with the base station device BS1, and is the radio communication system S1. In a frequency band to be used, a storage unit (database DB1 or interference information storage unit 2054) that stores interference information within a certain area and a storage unit (database DB1 or interference information storage unit 2054) for each frequency band. A scheduling unit (scheduling processing unit 2055) that schedules radio resources based on the stored interference information.
Thereby, a radio | wireless resource can be scheduled appropriately.

  Note that a part of the base station apparatus BS1 in the above-described embodiment, for example, the control unit 205 may be realized by a computer. In that case, the program for realizing the control function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read by a computer system and executed. Here, the “computer system” is a computer system built in the base station apparatus BS1, and includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” is a medium that dynamically holds a program for a short time, such as a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line, In such a case, a volatile memory inside a computer system serving as a server or a client may be included and a program that holds a program for a certain period of time. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  As described above, the embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the above, and various design changes and the like can be made without departing from the scope of the present invention. It is possible to

  (1) A wireless communication system including a base station device and a terminal device that communicates with the base station device, wherein a first measurement unit that measures first interference information and the first interference information Based on a second measurement unit that measures different second interference information, a storage unit that stores the first interference information and the second interference information, and the first interference information and the second interference information. And a scheduling unit that performs scheduling of radio resources.

  (2) The wireless communication system according to (1), wherein the first measurement unit further measures position information or time information, and the first interference information includes the position information.

  (3) The first measurement unit measures the first interference information for each frequency band, calculates received power of the measured first interference information, and the scheduling unit calculates the first interference information. The radio communication system according to (1) or (2), wherein radio resource scheduling is performed based on the received power of the first interference information and the second interference information.

  (4) A base station device that communicates with a terminal device, the receiving unit receiving first interference information measured by the terminal device, and second interference information different from the first interference information. A measurement unit; a storage unit that stores the first interference information and the second interference information; a scheduling unit that schedules radio resources based on the first interference information and the second interference information; A base station apparatus comprising:

  (5) A terminal apparatus that communicates with a base station apparatus, a measurement unit that measures first interference information, a report unit that reports the first interference information to the base station apparatus, and the first interference A terminal device comprising: a communication unit that communicates with the base station device using radio resources scheduled by the base station device based on information and second interference information measured by the base station device.

  (6) A wireless communication system including a base station device and a terminal device that communicates with the base station device, and within a certain area for each frequency band in the frequency band used in the wireless communication system A wireless communication system comprising: a storage unit that stores the interference information of the first communication unit; and a scheduling unit that performs scheduling of radio resources based on the interference information stored in the storage unit.

  (7) The scheduling unit has interference in one of an uplink frequency band and a downlink frequency band used for communication between the base station apparatus and the terminal apparatus based on the interference information. If so, the radio communication system according to (6), which performs scheduling without using the frequency band in which it is determined that the interference exists.

  (8) The scheduling unit uses an uplink frequency used in communication between the base station apparatus and the terminal apparatus according to a level of service request quality (QoS) or radio quality based on the interference information. The wireless communication system according to (6) or (7), wherein one or both frequency bands and downlink frequency bands are determined.

  (9) A base station device that communicates with a terminal device, comprising: a measurement unit that measures interference information; at least the interference information measured by the measurement unit; known interference information; and interference information from the terminal device. When receiving, a storage unit that stores at least one interference information with a statistical value of interference information received from each terminal device, and scheduling of radio resources based on the interference information stored in the storage unit And a scheduling unit.

  (10) A terminal device that communicates with a base station device, a measurement unit that measures first interference information, a report unit that reports the first interference information to the base station device, and the first interference A terminal device comprising: a communication unit that communicates with the base station device using radio resources scheduled by the base station device based on information and second interference information measured by the base station device.

  S1 ... Wireless communication system, DB1 ... Database, BS1, BS2, BS3 ... Base station device, UE1, UE2 ... Terminal device, 1011, 1012, 1013, 1014, 1015 ... Antenna, 1021 ... LTE transmitter A, 1022 ... LTE transmitter B, 1031 ... LTE receiver A, 1032 ... LTE receiver B, 104 ... interference wave receiver, 105 ... controller , 1051... Broadcast channel detection unit, 1052... Interference acquisition unit, 1053... Interference information report unit, 106... Position detection unit, 2011, 2012, 2013, 2014, 2015. ... LTE transmitter A, 2022 ... LTE transmitter B, 2031 ... LTE receiver A, 2032 ... LTE receiver B, 204 ... Wave receiving unit 205... Control unit 206 206 Interference information control unit 2051 Interference information receiving unit 2052 Interference wave detecting unit 2053 Interference information processing unit 2054. Interference information storage unit, 2055 ... scheduling processing unit

Claims (5)

A wireless communication system comprising a base station device and a terminal device that communicates with the base station device,
In a frequency band used in the wireless communication system, a storage unit that stores interference information in a certain area for each frequency band;
A scheduling unit for scheduling radio resources based on interference information stored in the storage unit;
A wireless communication system comprising: The scheduling unit includes
Based on the interference information, when it is determined that there is interference in one of the uplink frequency band and the downlink frequency band used in communication between the base station apparatus and the terminal apparatus, The wireless communication system according to claim 1, wherein scheduling is performed without using a frequency band determined to have interference. The scheduling unit includes
Based on the interference information, one or both of an uplink frequency band and a downlink used in communication between the base station apparatus and the terminal apparatus according to a level of service request quality (QoS) or radio quality The wireless communication system according to claim 1, wherein a frequency band of the wireless communication system is determined. A base station device that communicates with a terminal device,
A measurement unit for measuring interference information;
At least one interference information of at least the interference information measured by the measurement unit, known interference information, and a statistical value of interference information received from each terminal device when the interference information is received from the terminal device A storage unit for storing
A scheduling unit for scheduling radio resources based on the interference information stored in the storage unit;
A base station apparatus comprising: A terminal device that communicates with a base station device,
A measurement unit for measuring first interference information;
A reporting unit for reporting the first interference information to the base station device;
A communication unit that communicates with the base station device using radio resources scheduled by the base station device based on the first interference information and the second interference information measured by the base station device;
A terminal device comprising:

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