JP2007166488A - Radio communication system, radio channel monitoring apparatus, and radio communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio communication system in which an idle channel is detected in the smaller unit of a space than a service area formed by a base station so as to perform communication on the idle channel, and a radio channel monitoring apparatus and radio communication method. <P>SOLUTION: The radio communication method of the present invention includes: allocating radio channels to a plurality of radio terminals, respectively and using a radio channel commonly allocated to each of the radio terminals to monitor each of partial areas in a service area of a base station which performs radio communication; detecting radio channels which are not used by an existing system, respectively from the partial areas; detecting a radio terminal within each of the partial areas, allocating radio channels to the radio terminals on the basis of information of the unused radio channel, detected from each of the partial areas and information of the radio terminals detected from the partial areas; detecting that the allocated radio channel is used by the radio terminal; and notifying the radio terminal of interference detection information when interference is detected on the allocated radio channel. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a radio communication system, a radio channel monitoring apparatus, and a radio communication method, and more particularly to a cognitive radio communication technique.

  With the development of the information society, the number of communication means that can be used in familiar situations has increased dramatically, and the increase in communication speed has also been remarkable. In order to increase the communication speed, there are many examples in which a band that has been used for a specific application is used for a different application. For example, in general wireless communication, a law stipulates that a specific band is limited to a specific application, but some bands are open to a plurality of applications. In the future, there is a possibility that a very wide band such as UWB (Ultra-wideband) will be limited to low-power short-range communication and open to overlap with other applications. Furthermore, a study called a cognitive radio that allows unlicensed terminals to use the band currently licensed for a specific system only in places and times when the system is not in use has begun. (For example, refer to Patent Document 1).

The basic idea of cognitive radio is to scan a band that can be used to detect the usage status and to use it if it is not used. Therefore, it is necessary to use an unused radio channel so as not to interfere with a licensed terminal or an existing radio system as much as possible. Japanese Patent Laid-Open No. 2002-135831 (Patent Document 2) discloses a method of detecting interference of a license terminal or an existing wireless system and avoiding the interference. In this case, when the terminal detects interference, the terminal once reports to the base station, and the base station notifies all terminals that are associated using the broadcast channel to stop transmission. The feature of cognitive radio is not only to use unused radio channels, but also to communicate with other licensed terminals or existing radio systems spatially or temporally so as not to interfere, and use efficiency of radio band It is to improve. Therefore, it is necessary to determine whether to interfere with a license terminal or an existing wireless system spatially or locally. However, in Japanese Patent Laid-Open No. 2002-135831, the radio channel can only be controlled in units of service areas formed by the base station.
Japanese Patent No. 3583962 JP 2002-135831 A

  In cognitive radio, in order to improve frequency utilization efficiency, it is necessary to use a radio channel so as not to interfere with license terminals and existing radio systems in spatially fine units. However, conventionally, as disclosed in JP 2002-135831 A, in order to stop transmission so as not to interfere with the terminal after detecting interference, that is, transmission of another wireless system or licensed terminal, Is detected and notified to the base station, and the transmission of the terminal is stopped by the broadcast of the base station. Therefore, there is a problem that it takes time until the terminal transmission is stopped after the interference is detected, and the time during which the interference is given to other wireless systems becomes long. In addition, since the base station stops transmission of all terminals associated with the broadcast, the area where transmission stops is the service area unit formed by the base station and cannot be controlled in finer units. There was a problem that the frequency utilization efficiency was not improved.

  The present invention provides a wireless communication system, a wireless channel monitoring device, and a wireless communication method capable of detecting an empty channel in a space unit finer than a service area formed by a base station and performing communication using the empty channel. .

  A radio communication system according to an aspect of the present invention includes a base station that assigns radio channels to a plurality of radio terminals and performs radio communication using radio channels that are commonly assigned to the radio terminals, and the base station A wireless communication system comprising a plurality of wireless channel monitoring devices arranged in a service area of a station, wherein the wireless channel monitoring device monitors a partial area in the service area of the base station and is used by an existing system Channel detecting means for detecting a wireless channel that is not being used or being used; terminal detecting means for detecting a wireless terminal in the partial area; information on the detected wireless terminal; and the detected unused or Notifying means for notifying the base station of information on the radio channel in use, and the base station to the radio terminal Channel allocation information receiving means for receiving information on the assigned radio channel, and whether the radio terminal detects use of the assigned radio channel, and whether interference has occurred in the detected radio channel Interference detection means for monitoring the interference detection means for notifying the wireless terminal of interference detection information when the interference is detected, the base station is notified from the wireless channel monitoring device, Radio channel determining means for determining a radio channel to be allocated to the radio terminal in the partial area from the radio channel information that is not used or being used and information on the radio terminal, and a radio channel allocated to the radio terminal Allocation information notifying means for notifying at least the radio channel monitoring apparatus to which the radio terminal belongs. That, characterized in that.

  In the wireless communication system according to one aspect of the present invention, the wireless channel monitoring device assigns a wireless channel to each of a plurality of wireless terminals, and performs wireless communication using a wireless channel commonly assigned to each wireless terminal. A plurality of radio channel monitoring devices arranged in the service area of the base station, wherein a channel detection means for monitoring a partial area in the service area of the base station and detecting a radio channel not used or in use by an existing system And terminal detection means for detecting a wireless terminal in the partial area, information on the detected wireless terminal, and information on the detected unused or in-use wireless channel to the base station A channel for receiving information on a radio channel assigned to the radio terminal by the base station; Assignment information receiving means; interference detection means for detecting use of the assigned radio channel by the wireless terminal; and monitoring whether or not interference is occurring in the detected radio channel; and detecting the interference And an interference notification means for notifying the wireless terminal of interference detection information.

  According to one aspect of the present invention, there is provided a wireless communication method in which a wireless channel is assigned to each of a plurality of wireless terminals, and wireless communication is performed using wireless channels commonly assigned to the wireless terminals. The partial areas are monitored, radio channels not used by existing systems are detected from each partial area, wireless terminals in each partial area are detected, and the used ones detected from each partial area are detected. A wireless channel is allocated to each wireless terminal based on information on the wireless channel that is not available and information on the wireless terminal detected from each partial area, and whether the allocated wireless channel is used by the wireless terminal If the assigned radio channel is used, the assigned radio It monitors whether interference Yaneru is occurring, when the interference is detected and notifies the wireless terminals using the assigned radio channel interference detection information.

  According to the present invention, an empty channel can be detected in units of space smaller than the service area formed by the base station, and communication can be performed using the empty channel.

  FIG. 1 shows an example of a system configuration diagram for implementing the present invention. The cognitive radio system includes a cognitive base station 1001, a database 1002, a cognitive terminal A1003, a cognitive terminal B1004, a cognitive terminal C1005, a radio channel monitoring device A1006, a radio channel monitoring device B1007, and a radio monitoring device C1008. A cognitive radio system is a system that performs radio communication by sharing a radio channel used by a mobile phone system, a radio channel used by a wireless LAN system, and a radio band used by a radar. In addition, the cognitive radio system does not interfere with an existing radio system while sharing a radio channel. For example, when the cellular phone 1010 in FIG. 1 is not communicating, the cognitive terminal A 1003 and the cognitive terminal B 1004 communicate using the radio channel of the cellular phone system. Similarly, the radio channel used by the wireless LAN 1012 and the radio band used by the radar 1011 are used in the cognitive radio system so that the wireless LAN 1012 and the radar 1011 do not interfere with each other.

  Next, a method for detecting a free radio channel used by the cognitive terminal will be described. The radio channel monitoring device scans the frequency band of the existing system at regular intervals and measures RSSI (Received Signal Strength Indicator). For example, the wireless LAN and radar scan the 5 GHz band, and the mobile phone system scans the 800 MHz and 1.9 GHz bands. The scanning result is notified to the cognitive base station using a wireless control channel. Specifically, the cognitive base station polls the radio channel monitoring device to collect the scan results of each radio channel monitoring device. For information with a small amount of data such as scan results and control information, UWB (Ultra Wide Band) that does not interfere with existing wireless systems is used. FIG. 2 shows a sequence in which the cognitive base station polls the radio channel monitoring apparatus in order to collect the results of scanning the radio channel usage status of the existing system from the radio channel monitoring apparatus. The cognitive base station periodically performs such a polling sequence. The information between the radio channel monitoring apparatus and the cognitive base station can be communicated by connecting the radio channel monitoring apparatus and the cognitive base station with a wire in addition to being performed on the control radio channel using UWB.

  The cognitive terminal first associates with the cognitive base station in order to have the radio channel allocated from the cognitive base station. Association is performed by a radio control channel using UWB. At the same time, when the cognitive terminal associates, the radio channel monitoring apparatus receives the radio control channel transmitted by the cognitive terminal and acquires information on the cognitive terminal. And the information of the acquired cognitive terminal is notified to a cognitive base station simultaneously with a scanning result. In this manner, the cognitive base station determines a radio channel to be allocated to the cognitive terminal from the radio channel usage status of the existing system collected from each radio channel monitoring apparatus and the information of the cognitive terminal. For example, when a cognitive terminal exists in the monitoring range of a certain radio channel monitoring device, the cognitive base station allocates an empty radio channel in this monitoring range to this cognitive terminal. When the cognitive base station determines the radio channel to be allocated to the cognitive terminal, the determined content is stored in the database 1002. FIG. 3 shows an example of the database. In this example, radio channels up to the second candidate are allocated to each cognitive terminal. In FIG. 3, a cognitive terminal A is assigned a carrier frequency of 800 MHz as a first candidate and a use bandwidth of 1 MHz, a second candidate is assigned a carrier frequency of 1.9 GHz and a use bandwidth of 5 MHz, and cognitive terminal B is assigned a carrier frequency of 800 MHz as a first candidate. Use bandwidth 1MHz, assign carrier frequency 1.9GHz as second candidate, use bandwidth 5MHz, and cognitive terminal C has carrier frequency 5GHz, use bandwidth 20MHz as first candidate, carrier frequency 1.9GHz, use bandwidth 5MHz as second candidate Assign. The allocated information is reported to all the cognitive terminals by the cognitive base station through the control channel by UWB. The broadcast radio channel allocation information is received and stored in all cognitive terminals. The radio channel monitoring apparatus also receives and stores the allocation information broadcast from the cognitive base station (stores at least the radio channel information allocated to the cognitive terminals within its own monitoring range).

  Further, when the radio channel monitoring device is equipped with GPS, the latitude / longitude of the cognitive terminal position can be estimated from the latitude / longitude of the radio channel monitoring device and the arrival direction of the radio transmitted by the cognitive terminal and RSSI. Similarly, when scanning an existing system, the longitude and latitude of the terminal position of the existing system can be estimated from the arrival direction of the radio transmitted by the terminal of the existing system and RSSI. It is also possible to transmit the estimated latitude / longitude of the cognitive terminal, the latitude / longitude of the terminal of the existing system, and free channel information to the base station. The base station can also assign a radio channel to the cognitive terminal so as not to interfere with the terminal of the existing system from the position of the terminal of the existing system and the position of the cognitive terminal. For example, when the position of the cognitive terminal is separated from the position of the terminal of the existing system by a threshold or more, it may be determined that the frequency band used by the terminal of the existing system can be allocated to the cognitive terminal. At this time, the threshold may be determined based on the RSSI of the terminal of the existing system. Further, the position of the terminal of the existing system and the free channel information used for the determination may further be acquired by a radio channel monitoring apparatus other than the radio channel monitoring apparatus to which the focused cognitive terminal belongs.

  When the cognitive terminal A 1003 starts to communicate with the cognitive terminal B 1004, the cognitive terminal A is notified from the cognitive base station, searches the stored channel assignment information, and the cognitive terminal A and the cognitive terminal B are both assigned to the radio. Determine the channel. Since both the carrier frequency of 800 MHz and the use band of 1 MHz are allocated according to the database of FIG. 3, the cognitive terminal A starts communication using this radio channel. On the other hand, the radio channel monitoring apparatus A scans radio channels allocated to all terminals based on radio channel allocation information broadcasted and stored from the cognitive base station (at least allocated to cognitive terminals existing in its own monitoring range). And the cognitive terminal detects whether or not communication is performed. In addition, it also monitors for interference on the radio channel with which the cognitive terminal is communicating.

  Note that the cognitive base station notifies the cognitive terminal only of the information of the channel assigned to the terminal, and when the cognitive terminal starts communication, the communication is performed by negotiation using the UWB with the cognitive terminal as the communication partner. A wireless channel to be used may be determined.

  Assume that the cognitive terminal A 1003 and the cognitive terminal B 1004 communicate with each other on the 800 MHz radio channel, and the cognitive terminal A transmits to the cognitive terminal B. At this time, if the mobile phone 1010 starts communication on the 800 MHz radio channel, the cognitive terminal A 1003 interferes with the mobile phone 1010. Further, since the cognitive terminal A 1003 is transmitting, it cannot recognize that the mobile phone 1010 has started communication. On the other hand, the radio channel monitoring apparatus A1006 can monitor the radio channel transmitted by the cognitive terminal A1003 and detect whether interference has occurred on the radio channel. When the radio channel monitoring apparatus A1006 detects interference, it determines that the existing radio system has started transmission on the radio channel, and notifies the cognitive terminal A1003 that there is interference on the radio channel so as to stop transmission. The cognitive terminal A1003 notified from the radio channel monitoring apparatus A1006 immediately stops transmission so as not to interfere with the existing radio system. In this way, the radio channel monitoring apparatus detects the interference of the radio channel used by the cognitive terminal, and when the interference is detected, stops the transmission to the cognitive terminal, thereby minimizing the interference given to the existing radio system. I can do it.

  FIG. 4 shows an example of a configuration diagram of the radio channel monitoring apparatus. Control channel transmission / reception is performed by an antenna 4070 for transmitting / receiving a control channel, and a UWB receiver 4071 and a UWB transmitter 4072 connected thereto. An array antenna is configured by four antennas 4010 to 4013, and an RF / IF unit 4020 to 4023 that performs down-converter and channel selection and an A / D unit 4030 to 4033 that performs analog-digital conversion are connected to each antenna. . Radio signals received by the antennas 4010 to 4013 are converted into baseband signals in the RF / IF units 4020 to 4023, and further converted into digital signals in the A / D units 4030 to 4033, and then the incoming wave detection units 4041, The data is output to the omnidirectional synthesis unit 4051 and the directivity synthesis unit 4061. The incoming wave detection unit 4041 estimates from which direction the signal has arrived based on the signal received from the array antenna. When the received signals from the antennas 4010 to 4013 are combined, the omnidirectional combining unit 4051 combines the antennas so that the antenna directivity becomes omnidirectional. The synthesized signal is output to RSSI measuring section 4052, RSSI is measured, and the measured RSSI is passed to control section 4080. The combined signal is output to demodulation section 4053, demodulated by demodulation section 4053, received quality is measured by reception quality measurement section 4054, and the result is passed to control section 4080. The directivity combining unit 4061 combines the signals received from the antennas so that the antennas 4010 to 4013 direct the directivity in the arrival direction estimated by the incoming wave detection unit 4041. The RSSI measurement unit 4062 measures the RSSI of the synthesized signal and outputs the RSSI to the control unit 4080. At the same time, the combined signal is passed to the demodulator 4063, demodulated by the demodulator 4063, and then the reception quality is measured by the reception quality measurement 4064, and the result is passed to the controller 4080. When scanning whether an existing wireless system uses a radio channel, first, the arrival direction detection unit 4041 detects the arrival direction, then the directivity synthesis unit 4061 performs directivity synthesis, and the directivity synthesis The RSSI measurement unit 4062 measures RSSI using the obtained signal. Then, the position of the terminal or base station using the radio channel among the terminals and base stations of the existing radio system is estimated by the control unit 4080 from the detected arrival direction and measured data such as RSSI. Then, the radio channel used by the existing radio system and its position information are modulated into UWB by the UWB transmitter 4072 and notified to the cognitive base station. The radio channel monitoring device scans a control channel used when the cognitive terminal associates with the cognitive base station. The arrival wave detection unit 4041 estimates the arrival direction of the radio waves of the control channel, and the directivity synthesis unit 4061 synthesizes the signals received from the antennas so as to direct the directivity to the arrival direction. The RSSI measurement unit 4062 performs RSSI measurement using the signal obtained by the synthesis, the reception quality is measured by the demodulation unit 4063 and the reception quality measurement unit 4064, and the results (estimated arrival direction, measured RSSI, measured reception) The position of the cognitive terminal is estimated from the (quality). The estimated position of the cognitive terminal is notified to the cognitive base station by the UWB transmitter 4072. Based on the radio channel information assigned to the cognitive terminal notified from the cognitive base station, the radio channel monitoring apparatus scans the radio channel assigned for directivity to the associated cognitive terminal. For this purpose, the directivity combining unit 4061 is set to direct the antenna directivity to the associated cognitive terminal, and it is determined whether or not the cognitive terminal starts transmission by the output of the RSSI measuring unit 4062. Since directivity is directed to the cognitive terminal, it becomes possible to monitor with high accuracy. At the same time, the omnidirectional synthesis unit 4051 synthesizes the received signal of the cognitive terminal so as to be omnidirectional, and performs RSSI measurement in the RSSI measurement unit 4052 using the signal obtained by the synthesis. The reception quality is measured by the measurement unit 4054. In this way, by making RSS antennas non-directional and measuring RSSI and reception quality, if the existing radio system starts communication on the radio channel used by the cognitive terminal, the interference can be detected. . FIG. 14 shows an interference detection flowchart. When a signal is received (14001), it is checked whether the signal is demodulated normally (14002). It can be considered to determine whether or not the demodulation has been normally performed by, for example, a parity check, a CRC check, and a correlation with a known pattern. If it has been demodulated normally (YES in 14002), it is determined that there is no interference and the process ends (14003). If demodulation is not performed normally (NO in 14002), RSSI is measured (14004), and it is checked whether RSSI is increased more than when demodulated normally (14005). If it has not increased (NO in 14005), it is determined that there is no interference (for example, it is possible that demodulation could not be performed normally due to fading) (14003), and if it has increased (YES in 14005), it is determined that there is interference (14006). When the radio channel monitoring apparatus detects interference on the radio channel with which the cognitive terminal communicates, the modulation unit 4090 modulates a stop command in order to stop transmission to the cognitive terminal that is transmitting. The modulated signal is weighted for each antenna by the directivity weighting unit 4091 so that the directivity of the array antenna is directed to the cognitive terminal. Modulated signals weighted for each antenna are converted into analog signals by digital / analog converters A / D 4034 to 4037, up-converted by RF / IF units 4024 to 4027, and transmitted from antennas 4010 to 4013. Thus, by narrowing the directivity of the transmission stop signal, it is possible to prevent the transmission of the transmission stop signal from interfering with the existing wireless system.

  Next, a method in which the radio channel monitoring apparatus notifies the cognitive terminal of a transmission stop signal will be described in detail with reference to FIG. Assume that the cognitive terminal A5003 and the cognitive terminal B5004 are communicating by TDD (Time Division Duplex). At this time, it is assumed that the mobile phone 5010 starts communication on the wireless channel in which communication is performed with the cognitive terminal A5003 and the cognitive terminal A5003, and the wireless channel monitoring device A5006 detects it. Radio channel monitoring apparatus A5006 notifies cognitive terminal A5003 of the transmission stop in order to stop transmission of cognitive terminal A5003 that interferes with mobile phone 5010. When the cognitive terminal A 5003 and the cognitive terminal B 5004 transmit the message 5020, a field 5021 for transmitting nothing is provided. The radio channel monitoring apparatus A5006 transmits a transmission stop message 5022 to the cognitive terminal A5003 in synchronization with the timing of this field 5021. In this way, even when the cognitive terminal A5003 is receiving a message, the radio channel monitoring apparatus A5006 can notify the cognitive terminal A5003 of a transmission stop message and minimize interference with the mobile phone 5010. I can do it.

  FIG. 6 shows an example of the configuration of the cognitive terminal. The cognitive terminal transmits / receives a control channel using the UWB receiver 6011, the UWB transmitter 6012, and the antenna 6010. Radio channel allocation information broadcast from the cognitive base station is received by the UWB receiver 6011 and the information is stored in the control unit 6020. When starting communication, the radio channel is set according to the information assigned from the cognitive base station, the transmission signal is modulated by the modulation unit 6008, and the modulated signal is converted to an analog signal by the digital / analog converter D / A6007. Up-converted by the RF / IF unit 6006. Since the communication channel is TDD, transmission is performed via the antenna 6001 by connecting the switch 6002 to the RF / IF unit 6006. When receiving data on the communication channel, the switch 6002 is connected to the RF / IF unit 6003, and the received signal from the antenna 6001 is down-converted by the RF / IF unit 6003, channel selection is performed, and the digital signal is output from the A / D 6004. Is demodulated by the demodulator 6005.

  FIG. 7 shows a block diagram when the cognitive terminal is given directivity. The transmission / reception of the control channel is realized by UWB transceivers 7071 and 7072 as in FIG. Since the communication channel is TDD, the antennas 7010 to 7013 are connected to the RF / IF units 7024 to 7027 at the time of transmission, and are connected to the RF / IF units 7020 to 7023 at the time of reception. At the time of transmission, the directivity weighting unit 7091 weights the data modulated by the modulation unit 7090 so that the directivity is directed to the transmission destination cognitive terminal, and transmits the data. By doing so, it is possible to transmit to a transmission destination while minimizing interference with an existing wireless system. In the case of reception, the directivity combining unit 7061 combines signals from the respective antennas so that the antenna directivity is directed to the communication cognitive terminal, and the demodulation unit 7062 demodulates the signals. This makes it possible to receive with good quality. Further, since the transmission stop signal from the radio channel monitoring apparatus must be received as shown in FIG. 5, the directivity synthesis unit 7061 is set so that the antenna array becomes omnidirectional at the timing of the field 5021 in FIG. Set. In this way, communication between cognitive terminals can be performed well, and the transmission stop signal from the radio channel monitoring apparatus can be received by the cognitive terminal, and when there is interference, that is, the existing radio system starts communication. As soon as the cognitive terminal can stop transmitting.

(Second Embodiment)
Although the case where communication between cognitive terminals is performed by TDD has been described in the first embodiment, the case where communication between cognitive terminals is performed by FDD (Frequency Division Duplex) will be described in the second embodiment.

  Since it is FDD, the cognitive base station must collect a set of radio channels to be transmitted / received to each cognitive terminal after collecting information on an empty radio channel from the radio channel monitoring apparatus. FIG. 8 shows an example of the contents of the database 1002. Cognitive terminal A is assigned a carrier frequency of 800 MHz, a usage band of 1 MHz and a carrier frequency of 850 MHz, and 1 MHz as a pair of transmission / reception communication channels, and a carrier frequency of 1.9 GHz, a usage band of 5 MHz, a carrier frequency of 2 GHz, and a usage band of 5 MHz as second candidates. To do. Assume that the cognitive terminal B is also assigned the same radio channel as the cognitive terminal A. As in the first embodiment, the cognitive base station broadcasts these allocation information using the control channel, and each cognitive terminal and the radio channel monitoring apparatus receive and store the broadcast.

  FIG. 9 shows in detail how the radio channel monitoring apparatus notifies a cognitive terminal of a transmission stop signal when cognitive terminals communicate with each other by FDD. The message 9030 is transmitted from the cognitive terminal A9003 to the cognitive terminal B9004, and the cognitive terminal B9004 transmits the message 9020 to the cognitive terminal A9003. Fields 9031 and 9021 that are not transmitted for each message are provided. When the mobile phone 9010 starts communication on the transmission channel of the cognitive terminal A9003 and the radio channel monitoring apparatus A9006 detects this as interference, a transmission stop message 9022 is synchronized with the field 9021 in order to stop transmission of the cognitive terminal A9003. Then send. Even if the cognitive terminal A9003 is transmitting, since it is FDD and can receive simultaneously, the cognitive terminal A9003 can receive the transmission stop message and can immediately stop transmission. That is, as soon as the interference by the existing wireless system communicating by FDD is detected, the cognitive terminal transmission can be stopped, so that the interference given to the existing wireless system can be minimized.

(Third embodiment)
In the first embodiment, cognitive terminals communicate with each other by TDD. In this embodiment, the cognitive terminals perform carrier sense, and transmit if the radio channel is idle. Similarly, when the radio channel monitoring apparatus notifies the cognitive terminal of transmission stop, carrier sense is performed and transmission is performed if idle. FIG. 10 shows a block diagram in which carrier sense is performed for communication. Before the cognitive terminal A10003 transmits the message 10030, carrier sensing is performed for the period indicated by 10031, and transmission is performed if the radio channel is idle. Similarly, the cognitive terminal B10004 also performs carrier sense for the period indicated by 10021 before transmitting the message 10020, and transmits if idle. When the mobile phone 10010 starts communication and the radio channel monitoring device A10006 detects that there is interference on the radio channel used by the cognitive terminal A10003 and the cognitive terminal B10004, transmission between the cognitive terminal A10006 and the cognitive terminal B10004 Is sent to the cognitive terminal A10003. Before transmitting the message 10022, carrier sense is performed for the period indicated by 10025, and if it is idle, a transmission stop message 10022 is transmitted. At this time, the antenna array of the radio channel monitoring device A10006 is set so that directivity is directed to the cognitive terminal A10003 and the cognitive terminal B10004, and when determining whether the radio channel is idle, the influence of the mobile phone 10010 is reduced, and the cognitive It is determined whether transmission between the terminal A10003 and the cognitive terminal B10004 has been completed. Further, the carrier sense interval 10027 is set shorter than the carrier sense intervals 10031 and 10021 so that the transmission stop message can be transmitted with higher priority than the message transmission of the cognitive terminal. In this way, if there is interference from the existing radio system, the cognitive terminal can be notified directly of the transmission stop, and the cognitive terminal can be stopped, minimizing the interference to the existing radio system. I can do it.

(Fourth embodiment)
In the present embodiment, a case will be described in which cognitive terminal A and gognitive terminal B communicate by FDD as in the second embodiment and perform carrier sense before transmission. As in the second embodiment, the cognitive terminal A transmits at a carrier frequency of 800 MHz, and the cognitive terminal B transmits at a carrier frequency of 850 MHz. Each cognitive terminal scans the frequency to be transmitted before transmission, and transmits if it is idle. FIG. 11 shows a block diagram for performing the transmission. Before transmitting the message 11030, the cognitive terminal A11003 performs carrier sense of the radio channel of 800 MHz for the period shown in 11031, and transmits the message 11030 if the radio channel is idle. Similarly, the cognitive terminal B 11004 also performs carrier sense of a radio channel of 850 MHz for a period indicated by 11021, and transmits a message 11020 if idle. When the radio channel monitoring device A11006 detects that the mobile phone 11010 has started communication at a carrier frequency of 800 MHz as interference, a transmission stop signal is sent to the cognitive terminal A11003 using the carrier frequency 850 MHz in order to stop transmission of the cognitive terminal A11003. Send. At this time, carrier sense of a wireless channel of 850 MHz for a period shown in 11023 is performed, and if it is idle, a stop notification message 11022 is transmitted. The carrier sense time 11023 of the radio channel monitoring device is shorter than the carrier sense times 11031, 11021 performed by the cognitive terminal, and the priority of the transmission opportunity is increased, so that the transmission stop message can be quickly transmitted to the cognitive terminal. Therefore, even if the cognitive terminal is transmitting, a communication stop message can be notified. As described above, when CSMA (Carrier Sense Multiple Access) is introduced into FDD, it is possible to promptly notify a cognitive terminal that interferes with communication in an existing wireless system, quickly.

(Fifth embodiment)
In the present embodiment, in the case of the first embodiment, the radio channel monitoring apparatus notifies the cognitive terminal of transmission stop by UWB which is a control channel. The cognitive terminal can receive the transmission stop message through the control channel even when communicating on the communication channel, so that the transmission can be stopped immediately and the interference given to the existing wireless system can be minimized. Become.

(Sixth embodiment)
An example in which a TDD cellular system and a cognitive radio system share a radio channel as an existing radio system will be described. FIG. 12 shows an example of a system configuration diagram in which a TDD cellular system and a cognitive radio system share a radio channel. The cellular base station 12011 and the mobile terminal 12010 communicate with each other by TDD. An example of slot timing for communication using TDD is shown in FIG. In FIG. 13, three users are multiplexed, and downlink slots and uplink slots are time-division multiplexed. Therefore, at the timing of the uplink slot, the radio channel can be shared and used by the cognitive radio system unless interference is given to the cellular base station 12011. The radio channel monitoring apparatus or the cognitive terminal can detect the timing of the uplink slot and the downlink slot, the transmission timing assigned to each user, and the like by analyzing the signal of the downlink slot. Now, the cellular base station 12011 and the portable terminal are not communicating at the timing of the upstream slot, and the cognitive terminal A 12022 and the cognitive terminal B 12004 are communicating by sharing the wireless channel of the cellular system at the timing of the upstream slot. And At this time, when the mobile phone 12010 starts communication in the uplink slot, the cellular base station 12011 is interfered by the transmission of the cognitive terminal A 12022, and the cognitive terminal A 12022 is interfered by the transmission of the mobile phone 12010. In order to eliminate these interferences, the radio channel monitoring apparatus A12006 notifies the cognitive terminal A12022 that transmission is stopped by the methods of the first to fifth embodiments. The cognitive terminal A 12022 stops transmission and no longer interferes with the cellular base station 12011. In this way, the radio channel monitoring apparatus notifies the cognitive terminal of the transmission stop directly without going through the cognitive base station, so that the interference given to the existing radio system can be minimized, and the radio channel monitoring apparatus Are installed in the service area covered by the cognitive base station, the use permission of the radio channel can be controlled in a unit smaller than the service area, and the frequency use efficiency can be improved.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  The present invention can also be used for a ubiquitous system.

System configuration diagram related to implementation of the present invention The figure explaining the cognitive base station polling method Diagram showing database contents Wireless channel monitoring device configuration diagram Diagram showing how to stop sending Cognitive terminal block diagram Cognitive terminal block diagram Database contents at FDD The figure which shows the transmission stop notification at the time of FFD System configuration diagram for communication using CSMA System configuration diagram for communication by FDD and CSMA TDD cellular system and cognitive radio system configuration diagram TDD slot timing diagram Interference detection algorithm flowchart

Explanation of symbols

1001, 12001: Cognitive base station
1002, 12002: Database
1003 to 1005, 5003, 5004, 9003, 9004, 10003, 10004, 11003, 11004, 12022, 12004: Cognitive terminal
1006 to 1009, 5006, 9006, 10006, 11006, 12006: Radio channel monitoring device
1011: Radar
1012: Wireless LAN
1010, 5010, 9010, 10010, 11010, 12010: Mobile phones
4010 to 4013, 4070, 6001, 6010, 7010 to 7013, 7070: Antenna
4020 to 4027, 6003, 6006, 7020 to 7027: RF / IF section
4030 to 4037, 6004, 7030 to 7033: A / D part
4034-4037, 6007, 7034-7037: D / A part
4041: Arrival wave detector
4051: Omnidirectional synthesis unit
4052, 4062: RSSI measurement section
4053, 4063, 6005, 7062: Demodulator
4054, 4064: Receive quality measurement unit
4061, 7061: Directional synthesis unit
4071, 6011: UWB receiver
4072, 6012: UWB transmitter
4080, 6020, 7080: Control unit
4090, 6008, 7090: Modulator
4091, 7091: Directional weighting unit
5020, 9020, 9030, 10020, 10030, 11020, 11030: Message
5021, 9021, 9031: Fields that do not send anything
5022, 10022, 11022: Transmission stop message
6002, 7090 to 7093: Switch
10021, 10031, 10027, 11021, 11031, 11023: carrier sense period
12011: Cellular base station

Claims (8)

A radio channel is assigned to each of a plurality of radio terminals, and a base station that performs radio communication using radio channels commonly assigned to the radio terminals, and a plurality of radio channel monitors arranged in the service area of the base station A wireless communication system comprising a device,
The radio channel monitoring device includes:
Channel detection means for monitoring a partial area in the service area of the base station and detecting a radio channel not used or in use by an existing system;
Terminal detection means for detecting a wireless terminal in the partial area;
Notification means for notifying the base station of the detected information of the wireless terminal and the detected information of the unused or in-use wireless channel;
Channel assignment information receiving means for receiving information of a radio channel assigned to the radio terminal by the base station;
Interference detecting means for detecting use of the assigned radio channel by the radio terminal and monitoring whether interference has occurred in the radio channel for which use has been detected;
Interference notification means for notifying the wireless terminal of interference detection information when the interference is detected,
The base station
Radio channel determination means for determining a radio channel to be allocated to the radio terminal in the partial area from the radio channel information not used or being used and the radio terminal information notified from the radio channel monitoring device When,
Allocation information notifying means for notifying at least the radio channel monitoring apparatus to which the radio terminal belongs the information of the radio channel assigned to the radio terminal,
A wireless communication system.   The radio channel determination means in the base station allocates a radio channel that is not used by the existing system in a partial area monitored by the radio channel monitoring apparatus to a radio terminal existing in the partial area. The wireless communication system according to claim 1. The channel detection means in the radio channel monitoring device detects a position of a terminal using the radio channel in use;
The terminal detection means in the wireless channel monitoring device detects a position of the wireless terminal in the partial area;
The notifying means in the radio channel monitoring apparatus notifies the base station of the detected position information of the wireless terminal and the position information of the terminal,
The radio channel determination means in the base station is based on the detected location information of the radio terminal and the location information of the terminal using the radio channel in use, notified from the radio channel monitoring device. Determining a radio channel to be assigned to the radio terminal;
The wireless communication system according to claim 1. The frame transmitted and received between the wireless terminals has a transmission interruption field in which transmission is interrupted,
The interference notification means in the radio channel monitoring apparatus notifies the radio terminal of the interference detection information at the timing of the transmission interruption field in a frame transmitted to the radio terminal being monitored. A wireless communication system according to any one of the above. Further comprising the wireless terminal;
The wireless terminal is
An array antenna,
The period of the transmission interruption field in the transmitted frame makes the array antenna non-directional, and the period other than the transmission interruption field in the transmitted frame and the period of transmitting the frame are directivity of the array antenna. Directivity synthesis unit,
The wireless communication system according to claim 4, further comprising: Communication between the wireless terminals by CSMA (Carrier Sense Multiple Access),
The interference notification means in the radio channel monitoring apparatus notifies the radio terminal that is monitoring the interference detection information by CSMA in a carrier sense period shorter than a carrier sense period used between the radio terminals. The radio | wireless communications system in any one of Claim 1 thru | or 3. A radio channel monitoring apparatus arranged in a plurality of service areas of a base station that assigns radio channels to a plurality of radio terminals and performs radio communication using radio channels commonly assigned to the radio terminals,
Channel detection means for monitoring a partial area in the service area of the base station and detecting a radio channel not used or in use by an existing system;
Terminal detection means for detecting a wireless terminal in the partial area;
Notification means for notifying the base station of the detected information of the wireless terminal and the detected information of the unused or in-use wireless channel;
Channel assignment information receiving means for receiving information of a radio channel assigned to the radio terminal by the base station;
Interference detecting means for detecting use of the assigned radio channel by the radio terminal and monitoring whether interference has occurred in the radio channel for which use has been detected;
A radio channel monitoring device comprising: interference notifying means for notifying the radio terminal of interference detection information when the interference is detected. A wireless channel is assigned to each of a plurality of wireless terminals, and each partial area in a service area of a base station that performs wireless communication using a wireless channel commonly assigned to each wireless terminal is monitored. Detect each radio channel not used by existing systems,
Detect wireless terminals in each said partial area,
Based on the information on the unused radio channel detected from each partial area and the information on the wireless terminal detected from each partial area, a radio channel is allocated to each radio terminal,
Check whether the assigned radio channel is used by the radio terminal;
If the assigned radio channel is in use, monitor whether the assigned radio channel is interfering;
If the interference is detected, notify interference detection information to the wireless terminal using the allocated wireless channel,
Wireless communication method.

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