JP2013232782A - Communication device and communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid interference between radio systems due to failure in searching for available resources by reliably detecting available resources without searching for available resources.SOLUTION: A small base station device 100 operates as a relay device of a 4G radio system, and also operates as a base station device of a cognitive radio system. The small base station device 100 performs data transfer in communication using the 4G radio system. The small base station device 100 performs communication in the cognitive radio system. A transfer control unit 107 performs scheduling for transfer on the basis of line quality with a transfer destination when the transfer is performed. A cognitive control unit 114 controls such that communication in the cognitive radio system will be performed by use of available resources generated by scheduling in the transfer control unit 107.

Description

  The present invention relates to a communication apparatus and a communication method for performing communication between a cognitive radio system and a radio system other than the cognitive radio system, for example.

  In recent years, studies have been conducted on cognitive radio systems that make effective use of frequency resources by dynamically changing the frequency, bandwidth, communication system, and the like used for communication according to the usage situation. Among these, when using a frequency sharing type cognitive radio system that performs communication using the same resources as other radio systems, a search technique for free resources is required to prevent interference with other radio systems.

  Conventionally, as a free resource search technique, a method for searching for a free resource by providing a period for monitoring a signal of another wireless system is known (for example, Patent Document 1). In Patent Document 1, a carrier sense period is provided in a radio frame of a cognitive radio system, and signals of other radio systems are monitored. As a result of monitoring, if no signal of another wireless system is detected, it is determined that the resource is a free resource, and communication of the cognitive wireless system is performed using the free resource. This can prevent interference with other wireless systems.

  In addition, conventionally, a method of using a registered free lease when searching and registering a free resource in advance and starting communication is known (for example, Patent Document 2). In Patent Document 2, each wireless port such as a mobile station, a relay station, and a base station repeatedly searches and registers a free channel when there is no call request or connection request, and there is a call request or connection request. In this case, it is connected to the wireless port at the subsequent stage through the registered channel. In this way, resources can be shared between different wireless systems by performing line connection step by step while avoiding resources used in other systems.

JP 2008-78807 A JP 2002-135841 A

  However, in Patent Document 1, when the signal detection of another radio system fails even though there is a signal of another radio system within the carrier sense period, the transmission signal of the cognitive radio system is transmitted to the other radio system. There is a problem of interference. Further, in Patent Document 2, there is a problem that interference occurs between different wireless systems when a search for an empty channel fails and an empty channel is registered by mistake even though there is no empty channel. .

  An object of the present invention is to provide a communication device and a communication method capable of reliably detecting a free resource without searching for a free resource and avoiding interference between wireless systems due to a failure to search for a free resource. Is to provide.

  A communication device according to the present invention is a communication device that operates as a relay device of a first communication method and also operates as a base station device of a second communication method, and is configured to transmit data in communication using the first communication method. Scheduling for the transfer based on the line quality between the transfer means for performing the transfer, the communication means for performing the communication of the second communication method, and the transfer destination when performing the transfer, and the scheduling And a control unit that performs control so that communication of the second communication method is performed using the free resource generated by the above.

  The communication method of the present invention is a communication method in a communication device that operates as a relay device of the first communication method and operates as a base station device of the second communication method, and uses the first communication method. Performing the transfer of the data, performing the communication of the second communication method, scheduling for the transfer based on the line quality with the transfer destination when performing the transfer, and And controlling to perform communication of the second communication method using free resources generated by scheduling.

  According to the present invention, it is possible to reliably detect a free resource without searching for a free resource, and it is possible to avoid interference between wireless systems due to a failure to search for a free resource.

The figure which shows the structure of the communication system in Embodiment 1 of this invention. The block diagram which shows the structure of the small base station apparatus which concerns on Embodiment 1 of this invention. Sequence diagram showing operation in downlink of each device in Embodiment 1 of the present invention The figure which shows the transmission timing of the signal of a downlink in the case of performing only the data transmission of 4G radio | wireless system in Embodiment 1 of this invention. The figure which shows the transmission timing of the signal of a downlink in the case of performing both the data transmission of 4G radio | wireless system in Embodiment 1 of this invention, and the data transmission of a cognitive radio | wireless system. FIG. 3 is a sequence diagram showing an operation of each device in the uplink according to the first embodiment of the present invention. The figure which shows the transmission timing of the signal of an uplink in the case of performing only the data transmission of 4G radio | wireless system in Embodiment 1 of this invention. The figure which shows the transmission timing of the signal of an uplink in the case of performing both the data transmission of 4G radio | wireless system and the data transmission of a cognitive radio | wireless system in Embodiment 1 of this invention. The block diagram which shows the structure of the small base station apparatus which concerns on Embodiment 2 of this invention. Sequence diagram showing operation in downlink of each device in Embodiment 2 of the present invention Sequence diagram showing uplink operation of each apparatus in Embodiment 2 of the present invention

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  In the embodiment of the present invention, the other radio system is a 4G radio system (3GPP LTE (Long Term Evolution) -Advanced) (first communication scheme), and the downlink of the cognitive radio system (second communication scheme) is used. A case will be described as an example where OFDM and uplink are SC-FDMA. In the embodiment of the present invention, a case where a frequency sharing type cognitive radio system is used will be described.

  In the present invention, the other wireless system may be other than the 4G wireless system. In the present invention, the cognitive radio system may use a communication scheme other than the above for the uplink and the downlink.

(Embodiment 1)
<Configuration of communication system>
The configuration of the communication system 10 according to Embodiment 1 of the present invention will be described with reference to FIG. FIG. 1 is a diagram showing a configuration of a communication system 10 in the present embodiment.

  The communication system 10 mainly includes a 4G base station device 20, a 4G communication terminal device 30, a cognitive communication terminal device 40, and a small base station device 100.

  The 4G base station apparatus 20 is a base station apparatus that performs communication in a 4G wireless system. The 4G base station apparatus 20 transmits downlink data to the 4G communication terminal apparatus 30 via the small base station apparatus 100, or directly transmits downlink data to the 4G communication terminal apparatus 30. The 4G base station apparatus 20 receives uplink data from the 4G communication terminal apparatus 30 via the small base station apparatus 100, or directly receives uplink data from the 4G communication terminal apparatus 30.

  The 4G communication terminal device 30 is a communication terminal device that performs communication in a 4G wireless system. The 4G communication terminal apparatus 30 receives the downlink data transmitted from the 4G base station apparatus 20 via the small base station apparatus 100 or receives the downlink data transmitted from the 4G base station apparatus 20 from the 4G base station apparatus 20. Receive directly. The 4G communication terminal apparatus 30 transmits uplink data to the 4G base station apparatus 20 via the small base station apparatus 100, or directly transmits uplink data to the 4G base station apparatus 20.

  The cognitive communication terminal device 40 is a communication terminal device that performs communication in a frequency sharing type cognitive radio system. The cognitive communication terminal device 40 receives downlink data from the small base station device 100. The cognitive communication terminal device 40 transmits uplink data to the small base station device 100.

  The small base station apparatus 100 is a base station apparatus that performs communication using a 4G radio system and a frequency sharing type cognitive radio system. Specifically, the small base station apparatus 100 has a function of a 4G relay station that relays wireless communication between the 4G base station apparatus 20 and the 4G communication terminal apparatus 30. The small base station apparatus 100 has a function of a base station apparatus of a cognitive radio system that performs radio communication with the cognitive communication terminal apparatus 40.

  In the communication system 10, wireless communication between the 4G base station apparatus 20 and the small base station apparatus 100, wireless communication between the small base station apparatus 100 and the 4G communication terminal apparatus 30, and cognitive communication with the small base station apparatus 100. Wireless communication with the terminal device 40 is operated at the same frequency. In addition, radio communication between the 4G base station apparatus 20 and the small base station apparatus 100 and radio communication between the small base station apparatus 100 and the 4G communication terminal apparatus 30 are time-division multiplexed.

<Configuration of small base station device>
The configuration of small base station apparatus 100 according to Embodiment 1 of the present invention will be described using FIG. FIG. 2 is a block diagram showing a configuration of small base station apparatus 100 according to the present embodiment.

  Transfer data generation unit 108, error correction coding unit 109, data modulation unit 110, resource mapping unit 111, RF unit 112, antenna 113, error correction coding unit 128, data modulation unit 129, DFT unit 130, resource mapping unit 131 , RF unit 132 and antenna 133 constitute transfer means for transferring data of the 4G wireless system.

  Cognitive transmission data generation unit 115, error correction coding unit 116, data modulation unit 117, resource mapping unit 118, RF unit 119, antenna 120, antenna 121, RF unit 122, resource demapping unit 123, IDFT unit 134, data demodulation The unit 135 and the error correction decoding unit 136 constitute a communication unit that performs communication in the cognitive radio system.

  The small base station apparatus 100 includes a downlink processing unit 170 and an uplink processing unit 180. The downlink processing unit 170 performs transfer of the 4G wireless system in the downlink or communication of the cognitive wireless system in the downlink. The uplink processing unit 180 performs transfer of the 4G wireless system in the uplink or communication of the cognitive wireless system in the uplink.

  The antenna 101 receives a radio signal and outputs it to the RF unit 102. A signal received by the antenna 101 is a signal transferred from the 4G base station apparatus 20 to the 4G communication terminal apparatus 30.

  The RF unit 102 down-converts the received signal input from the antenna 101 and performs synchronization processing. Thereafter, the RF unit 102 removes the guard interval from the received signal, performs fast Fourier transform (FFT) on the received signal, and outputs the result to the resource demapping unit 103.

  The resource demapping unit 103 extracts the frequency components (subcarriers or resource blocks) of the control signal unit and the data signal unit included in the received signal from the received signal subjected to the fast Fourier transform input from the RF unit 102, and data Output to demodulator 104. Here, in order to search for control information addressed to itself, the control signal unit selects one from a plurality of known resource candidates and is extracted based on the information. The data signal part is extracted based on the demapping information of the data signal input from the data decoding part 106 after decoding the control information described later.

  The data demodulation unit 104 demodulates the frequency components of the control signal unit and the data signal unit input from the resource demapping unit 103 and outputs the demodulated signals of the control signal unit and the data signal unit to the error correction decoding unit 105. Here, the control signal unit is demodulated based on known demodulation information. The data signal portion is demodulated based on the demodulation information of the data signal input from the data decoding portion 106 after decoding the control information described later.

  The error correction decoding unit 105 performs error correction decoding on the control signal unit and the demodulated signal of the data signal unit input from the data demodulation unit 104, outputs the decoded data of the control signal unit to the data decoding unit 106, and outputs the data signal The decoded data is output to the transfer data generation unit 108. Here, the control signal unit is decoded based on known decoding information. The data signal part is decoded based on the decoding information of the data signal input from the data decoding part 106 after decoding the control information. The error correction decoding unit 105 also has a rate mismatch function, but a detailed description of the processing is omitted.

  The data decoding unit 106 extracts control information included in the decoded data input from the error correction decoding unit 105 and reads the extracted control information. Specifically, the data decoding unit 106 includes demapping information of a corresponding data signal, demodulation information for demodulating the data signal, decoding information for decoding the data signal, data size information, and a transfer destination 4G communication terminal. The transfer destination information for identifying the device 30 and the 4G uplink scheduling information for small base station transmission are read and interpreted. The data decoding unit 106 outputs the demapping information of the data signal to the resource demapping unit 103, outputs the demodulation information of the data signal to the data demodulation unit 104, and outputs the decoding information and the data size information of the data signal to the error correction decoding unit. The data size information, the transfer destination information, and the 4G uplink scheduling information for small base station transmission are output to the transfer control unit 107. Here, the small base station transmission 4G uplink scheduling information is generated in the 4G base station device 20 using a known signal periodically transmitted from the small base station device 100, and the small base station device 100 and the 4G base station. This is information generated based on the line quality information with the device 20.

  The transfer control unit 107 performs transfer based on the data size information and the transfer destination information input from the data decoding unit 106 and the 4G downlink quality information received from the 4G communication terminal device 30 input from the data decoding unit 127. And 4G downlink scheduling information for small base station transmission is determined. Here, the 4G downlink scheduling information for small base station transmission is resource allocation information, modulation information, demodulation information, coding information, and decoding information when a 4G data signal received from the 4G base station apparatus 20 is transferred.

  Based on the 4G uplink scheduling information for small base station transmission input from the data decryption unit 106 and the uplink 4G uplink quality information input from the data decryption unit 127, the transfer control unit 107 determines the 4G communication terminal apparatus 30 Uplink scheduling is performed and uplink scheduling information for 4G terminal transmission is determined. Here, the 4G terminal transmission uplink scheduling information is resource allocation information, modulation information, demodulation information, coding information, and decoding information for the 4G communication terminal apparatus 30 to transmit a data signal of the 4G wireless system.

  The transfer control unit 107 outputs the 4G downlink scheduling information for small base station transmission and the uplink scheduling information for 4G terminal transmission to the transfer data generation unit 108 and the cognitive control unit 114. Transfer control section 107 outputs the encoded information to error correction encoding section 109, outputs the modulation information to data modulation section 110, and outputs the resource allocation information to resource mapping section 111.

  The transfer control unit 107 outputs resource allocation information to the resource demapping unit 123, outputs demodulation information to the data demodulation unit 125, and outputs decoding information to the error correction decoding unit 126 during uplink operation.

  The transfer data generation unit 108 generates control information for transfer based on the 4G downlink scheduling information for small base station transmission and the uplink scheduling information for 4G terminal transmission input from the transfer control unit 107. The transfer data generation unit 108 outputs the generated control information and the decoded data of the data signal (transfer payload data) unit input from the error correction decoding unit 105 to the error correction encoding unit 109.

  Based on the encoding information input from the transfer control unit 107, the error correction encoding unit 109 performs error correction encoding on the control information input from the transfer data generation unit 108 and the decoded data of the data signal unit, respectively. The encoded data is output to the data modulation unit 110. The error correction encoding unit 109 also has a rate matching function, but the description thereof is omitted.

  The data modulation unit 110 modulates the encoded data input from the error correction encoding unit 109 based on the modulation information input from the transfer control unit 107, and outputs the modulated signal to the resource mapping unit 111.

  Based on the resource allocation information input from the transfer control unit 107, the resource mapping unit 111 maps the modulation signal input from the data modulation unit 110 to an appropriate frequency and an appropriate time, and outputs the result to the RF unit 112.

  The RF unit 112 performs an inverse fast Fourier transform (IFFT) on the signal input from the resource mapping unit 111 and inserts a guard interval. Further, the RF unit 112 up-converts the signal with the guard interval inserted and outputs it to the antenna 113.

  The antenna 113 transmits a signal input from the RF unit 112.

  The cognitive control unit 114 accesses the network and checks whether or not there is a cognitive communication terminal device 40 that requires cognitive communication. When the cognitive communication terminal device 40 exists, the cognitive control unit 114 detects a free resource from the 4G downlink scheduling information for small base station transmission input from the transfer control unit 107. Here, the vacant resource is a resource that is not used in the 4G wireless system in the small base station device 100 among resources that can be used in data transfer of the 4G wireless system. The free resource is, for example, frequency, time, or code.

  When there is an available resource, the cognitive control unit 114 performs cognitive transmission scheduling using the available resource, and determines cognitive downlink scheduling information. The cognitive control unit 114 acquires payload data having a transmittable data size from the network based on the cognitive downlink scheduling information. The cognitive control unit 114 activates the cognitive transmission function unit 150 and outputs the acquired payload data and cognitive downlink scheduling information to the cognitive transmission data generation unit 115. Here, the cognitive downlink scheduling information is resource allocation information, modulation information, demodulation information, coding information, and decoding information when the small base station apparatus 100 transmits a signal of the cognitive radio system.

  The cognitive control unit 114 detects free resources at the time of transfer from the uplink scheduling information for 4G terminal transmission input from the transfer control unit 107.

  When there is a free resource, the cognitive control unit 114 performs cognitive reception scheduling using the free resource, and determines cognitive uplink scheduling information. The cognitive control unit 114 outputs the determined cognitive uplink scheduling information to the cognitive transmission data generation unit 115. Here, the cognitive uplink scheduling information is resource allocation information, modulation information, demodulation information, coding information, and decoding information when the cognitive communication terminal apparatus 40 performs cognitive transmission.

  During the downlink operation of the cognitive radio system, the cognitive control unit 114 outputs encoded information in the downlink of the cognitive radio system to the error correction encoding unit 116, outputs the modulation information to the data modulation unit 117, and allocates resources. Information is output to the resource mapping unit 118.

  The cognitive control unit 114 outputs resource allocation information in the uplink of the cognitive radio system to the resource demapping unit 123 during the uplink operation of the cognitive radio system. Further, the cognitive control unit 114 activates the cognitive reception function unit 160, outputs demodulation information to the data demodulation unit 135, and outputs decoding information to the error correction decoding unit 136.

  Further, the cognitive control unit 114 outputs the decoded data (payload data) input from the error correction decoding unit 136 to the network.

  The cognitive transmission data generation unit 115 generates cognitive transmission control information based on the cognitive downlink scheduling information or the cognitive uplink scheduling information input from the cognitive control unit 114. The cognitive transmission data generation unit 115 outputs the generated control information and the payload data input from the cognitive control unit 114 to the error correction encoding unit 116.

  Based on the encoded information input from the cognitive control unit 114, the error correction encoding unit 116 performs error correction encoding on the control information and payload data input from the cognitive transmission data generation unit 115, and converts the encoded data into The data is output to the data modulation unit 117. The error correction encoding unit 116 also has a rate matching function, but a detailed description of the processing is omitted.

  The data modulation unit 117 modulates the encoded data input from the error correction encoding unit 116 based on the modulation information input from the cognitive control unit 114, and outputs the modulation signal to the resource mapping unit 118.

  Based on the resource allocation information input from the cognitive control unit 114, the resource mapping unit 118 maps the modulation signal input from the data modulation unit 117 to an appropriate frequency and an appropriate time, and outputs the mapped signal to the RF unit 119.

  The RF unit 119 performs fast inverse Fourier transform on the signal input from the resource mapping unit 118 and inserts a guard interval. Further, the RF unit 119 up-converts the signal with the guard interval inserted and outputs it to the antenna 120.

  The antenna 120 transmits a signal input from the RF unit 119.

  The antenna 121 receives a signal and outputs it to the RF unit 122. The signal received by the antenna 121 is a signal transmitted from the 4G communication terminal apparatus 30 to the 4G base station apparatus 20 or a signal transmitted from the cognitive communication terminal apparatus 40.

  The received signal input from the RF unit 122 and the antenna 121 is down-converted and synchronized. Thereafter, the RF unit 122 removes the guard interval from the received signal, performs fast Fourier transform on the received signal, and outputs the result to the resource demapping unit 123.

  The resource demapping unit 123 extracts the frequency component (subcarrier or resource block) of the received signal from the received signal input from the RF unit 122. The resource demapping unit 123 performs 4G communication based on the uplink resource allocation information of the 4G radio system input from the transfer control unit 107 and the uplink resource allocation information of the cognitive radio system input from the cognitive control unit 114. The 4G data signal transmitted from the terminal device 30 and the cognitive data signal transmitted from the cognitive communication terminal device 40 are extracted. The resource demapping unit 123 outputs the extracted 4G data signal to the IDFT unit 124, and outputs the extracted cognitive data signal to the IDFT unit 124. The resource demapping unit 123 extracts a known signal periodically transmitted from the 4G communication terminal device 30 and outputs the extracted known signal to the data decoding unit 127.

  The IDFT unit 124 performs an inverse discrete Fourier transform (IDFT) on the 4G data signal input from the resource demapping unit 123 and outputs the result to the data demodulation unit 125.

  The data demodulation unit 125 demodulates the 4G data signal input from the IDFT unit 124 based on the demodulation information input from the transfer control unit 107 and outputs the demodulated signal to the error correction decoding unit 126.

  The error correction decoding unit 126 performs error correction decoding on the demodulated signal input from the data demodulation unit 125 based on the decoding information input from the transfer control unit 107, and outputs the decoded data to the data decoding unit 127. Note that the error correction decoding unit 126 also performs rate dematching processing using the data size information input from the transfer control unit 107, but detailed description of the processing is omitted.

  The data decoding unit 127 extracts the payload data for transfer or the downlink 4G downlink quality information between the small base station device 100 and the 4G communication terminal device 30 from the decoded data input from the error correction decoding unit 126. . The data decoding unit 127 outputs the extracted payload data for transfer to the error correction encoding unit 128, and outputs the extracted 4G downlink quality information to the transfer control unit 107. The data decoding unit 127 uses the known signal input from the resource demapping unit 123 to measure the uplink channel quality between the 4G communication terminal apparatus 30 and the small base station apparatus 100, and the measurement result is output to the 4G uplink. It outputs to the transfer control part 107 as quality information.

  Based on the encoding information input from the transfer control unit 107, the error correction encoding unit 128 performs error correction encoding on the payload data for transfer input from the data decoding unit 127, and modulates the encoded data to data. Output to the unit 129. The error correction encoding unit 128 also has a rate matching function, but a detailed description of the processing is omitted.

  The data modulation unit 129 modulates the encoded data input from the error correction encoding unit 128 based on the modulation information input from the transfer control unit 107 and outputs the modulation signal to the DFT unit 130.

  The DFT unit 130 performs a discrete Fourier transform (DFT) on the modulation signal input from the data modulation unit 129 and outputs the result to the resource mapping unit 131.

  Based on the resource allocation information input from the transfer control unit 107, the resource mapping unit 131 maps the signal input from the DFT unit 130 to an appropriate frequency and an appropriate time, and outputs the signal to the RF unit 132.

  The RF unit 132 performs fast inverse Fourier transform on the signal input from the resource mapping unit 131 and inserts a guard interval. Further, the RF unit 132 up-converts the signal with the guard interval inserted and outputs it to the antenna 133.

  The antenna 133 transmits the signal input from the RF unit 132.

  The IDFT unit 134 performs discrete inverse Fourier transform on the cognitive data signal input from the resource demapping unit 123 and outputs the result to the data demodulation unit 135.

  Data demodulation section 135 demodulates the cognitive data signal input from IDFT section 134 based on the demodulation information input from cognitive control section 114 and outputs the demodulated signal to error correction decoding section 136.

  The error correction decoding unit 136 performs error correction decoding on the demodulated signal input from the data demodulation unit 135 based on the decoding information input from the cognitive control unit 114, and outputs the decoded data to the cognitive control unit 114. The error correction decoding unit 136 also performs rate dematching processing using the data size information input from the cognitive control unit 114, but detailed description of the processing is omitted.

<Operation of each device in downlink>
The operation of each device in the downlink according to Embodiment 1 of the present invention will be described with reference to FIG. FIG. 3 is a sequence diagram showing an operation in the downlink of each device in the present embodiment.

  First, the small base station apparatus 100 receives 4G downlink quality information from the 4G communication terminal apparatus 30 (step ST301). At this time, the 4G communication terminal apparatus 30 periodically receives a known signal transmitted from the small base station apparatus 100, and generates 4G downlink quality information using the received known signal. Here, the known signal is, for example, a reference signal, a broadcast channel, or a synchronization signal.

  Further, the small base station apparatus 100 receives a downlink data signal from the 4G base station apparatus 20 (step ST302).

  Next, the small base station apparatus 100 decodes the control information from the downlink data signal received in step ST302 in the data decoding unit 106, and obtains data size information, transfer destination information, and 4G uplink scheduling information for small base station transmission. Obtain (step ST303).

  Next, in the small base station apparatus 100, the transfer control unit 107 uses the 4G downlink quality information received in step ST301, the data size information acquired in step ST303, the transfer destination information, and the 4G uplink scheduling information for small base station transmission. Based on the above, the 4G wireless system is scheduled. That is, the transfer control unit 107 performs transfer scheduling and uplink scheduling of the 4G communication terminal apparatus 30 (step ST304).

  In the transfer scheduling, the transfer control unit 107 selects the 4G downlink quality information of the corresponding 4G communication terminal apparatus 30 based on the transfer destination information. Thereafter, the transfer control unit 107 assigns resources used for transfer to frequencies and times with good channel quality in which the channel quality of the 4G downlink quality information is equal to or higher than a threshold. Also, the transfer control unit 107 determines the coding rate and the modulation multi-level number when performing transfer based on the 4G downlink quality information and the transmission data size.

  In the uplink scheduling of the 4G communication terminal apparatus 30, the transfer control unit 107, between the small base station apparatus 100 and the 4G base station apparatus 20, follows the uplink schedule information received from the 4G base station apparatus 20, A modulation multi-level number, a coding rate, and resource allocation at the time of transfer are determined. Further, the small base station apparatus 100 measures the uplink line quality between the 4G communication terminal apparatus 30 and the small base station apparatus 100 in the data decoding unit 127 and generates 4G uplink quality information. The transfer control unit 107 performs resource allocation for the frequency and time with good channel quality in which the channel quality of the 4G uplink quality information is equal to or higher than the threshold. Also, the transfer control unit 107 determines the coding rate and the modulation multi-level number when performing the transfer based on the 4G uplink quality information and the scheduled reception data size.

  Next, the small base station apparatus 100 adds the small base station transmission 4G downlink scheduling information and the 4G terminal transmission uplink scheduling information determined in step ST304 to the transfer data in the transfer data generation unit 108 (step ST305). .

  Next, small base station apparatus 100 determines the presence or absence of cognitive communication terminal apparatus 40 that performs cognitive communication in cognitive control section 114 (step ST306).

  When it is determined that there is no cognitive communication terminal device 40 (step ST306: NO), the small base station device 100 starts downlink data transfer to the 4G communication terminal device 30 (step ST307).

  On the other hand, when it is determined that the cognitive communication terminal device 40 is present (step ST306: YES), the small base station device 100 uses the cognitive control unit 114 to transmit the 4G downlink scheduling information for small base station transmission determined in step ST304. Free resources are detected (step ST308).

  Next, the cognitive control unit 114 determines whether there is a free resource (step ST309).

  If it is determined that the cognitive radio system cannot be transmitted because there is no free resource (step ST309: NO), the small base station device 100 does not transmit the cognitive radio system and transmits downlink data to the 4G communication terminal device 30. The transfer is started (step ST307).

  On the other hand, when it is determined that transmission of the cognitive radio system is possible because there are free resources (step ST309: YES), the cognitive control unit 114 performs scheduling of downlink and uplink of the cognitive radio system using the free resources. Is performed (step ST310). Specifically, the cognitive control unit 114 allocates free resources for downlink transmission to the cognitive communication terminal apparatus 40 and uplink reception from the cognitive communication terminal apparatus 40. In addition, the cognitive control unit 114 determines the cognitive data signal having a size that can be transmitted with free resources, with the modulation multi-level number and the coding rate fixed.

  In addition, small base station apparatus 100 adds cognitive downlink scheduling information and cognitive uplink scheduling information determined in step ST310 to cognitive transmission data in cognitive transmission data generation section 115 (step ST311).

  Next, the small base station apparatus 100 transmits the downlink data signal of the cognitive data radio system to the cognitive communication terminal apparatus 40 (step ST312), and transfers the downlink data signal of the 4G radio system to the 4G communication terminal apparatus 30 ( Step ST307).

<Signal transmission / reception method in downlink>
A downlink signal transmission / reception method according to Embodiment 1 of the present invention will be described with reference to FIGS. FIG. 4 is a diagram illustrating downlink signal transmission timing when only data transmission of the 4G wireless system in the present embodiment is performed. FIG. 5 is a diagram illustrating a transmission timing of a downlink signal when performing both data transmission of the 4G wireless system and data transmission of the cognitive wireless system in the present embodiment.

  First, downlink signal transmission timing when only data transmission of a 4G wireless system is performed will be described with reference to FIG.

  In FIG. 4, the small base station apparatus 100 only performs transmission signal transmission from the 4G base station apparatus 20 to the 4G communication terminal apparatus 30. The transfer by the small base station apparatus 100 is performed in units of subframes. In the transfer of the 4G wireless system, there are two timings, the timing at which the 4G base station apparatus 20 transmits to the small base station apparatus 100 and the timing at which the small base station apparatus 100 transmits to the 4G communication terminal apparatus 30. Here, each timing unit is a subframe. One subframe signal is composed of a 4G data signal 411a and a 4G control signal 411b. The 4G control signal 411b includes data size information of the 4G data signal 411a, demodulation information and decoding information for demodulating and decoding the 4G data signal 411a, resource allocation information, and transfer destination information. Since the small base station apparatus 100 decodes the 4G control signal 411b and generates a 4G data signal for transfer to the 4G communication terminal apparatus 30, a transfer delay occurs for the time required for the processing. Therefore, the small base station apparatus 100 transfers the signal from the 4G base station apparatus 20 to the 4G communication terminal apparatus 30 after the second subframe from the subframe received.

  FIG. 4 assumes a case where the delay for transfer is smaller than 2 subframes. In subframe 1, 4G base station apparatus 20 transmits control signal 411b and 4G data signal 411a to small base station apparatus 100 (step ST401). Here, the control signal 411b is a control signal addressed to the small base station apparatus 100.

  In subframes 2 and 3, the small base station apparatus 100 reads the control signal 411b received from the 4G base station apparatus 20 in subframe 1 and decodes the 4G data signal 411a. Thereafter, the small base station apparatus 100 generates a 4G control signal 412b addressed to the 4G communication terminal apparatus 30 and a 4G data signal 412a for transfer. In subframe 2, small base station apparatus 100 transfers a signal received from 4G base station apparatus 20 in a subframe (not shown) before subframe 1 to 4G communication terminal apparatus 30 (step ST402).

  In subframe 3, small base station apparatus 100 receives a 4G radio system signal newly transmitted from 4G base station apparatus 20 (step ST403).

  In subframe 4, the small base station apparatus 100 sends a 4G control signal 412b addressed to the 4G communication terminal apparatus 30 generated in subframes 2 and 3 and a 4G data signal 412a for transfer to the 4G communication terminal apparatus 30. Transfer (step ST404).

  Thereafter, this process is repeated for each subframe. Thus, since the wireless communication between the 4G base station apparatus 20 and the small base station apparatus 100 and the wireless communication between the small base station apparatus 100 and the 4G communication terminal apparatus 30 are performed at different times, Interference does not occur even when operating at the same frequency. Furthermore, since the small base station apparatus 100 does not need to process transmission and reception at the same time, it does not receive the transmitted signal itself.

  Next, the transmission timing of the downlink signal when performing both data transmission of the 4G radio system and data transmission of the cognitive radio system will be described with reference to FIG.

  The small base station apparatus 100 performs transmission of the cognitive radio system to the cognitive communication terminal apparatus 40 in addition to the transfer of data of the 4G radio system from the 4G base station apparatus 20 to the 4G communication terminal apparatus 30. The basic transfer timing and frame format are the same as in FIG. In the transmission of the cognitive radio system in the small base station apparatus 100, the resources that can be allocated are variable according to the amount of data transferred between the small base station apparatus 100 and the 4G communication terminal apparatus 30, so that there are three transmission patterns. Conceivable.

  Transmission pattern 1 will be described using subframes 11 to 14 in FIG. Transmission pattern 1 is a case where all resources are used to transfer a 4G data signal. First, in subframe 11, 4G base station apparatus 20 transmits 4G control signal 511b and 4G data signal 511a to small base station apparatus 100 (step ST501). In FIG. 5, the 4G base station apparatus 20 uses all resources for transmission to the small base station apparatus 100, but uses only some resources for transmission to the small base station apparatus 100. Also good.

  In subframes 12 and 13 (not shown), the small base station device 100 reads the 4G control signal 511b received in the subframe 11 from the 4G base station device 20 in the data decoding unit 106, and the 4G data in the error correction decoding unit 105. The signal 511a is decoded. After that, the small base station apparatus 100 checks free resources when the 4G data signal is transferred in the cognitive control unit 114. When there is no free resource, the small base station device 100 generates only the 4G control signal 512b addressed to the 4G communication terminal device 30 and the 4G data signal 512a for transfer.

  In subframe 14, small base station apparatus 100 transfers 4G control signal 512b addressed to 4G communication terminal apparatus 30 and 4G data signal 512a for transfer to 4G communication terminal apparatus 30 (step ST502). At this time, the small base station apparatus 100 does not perform transmission to the cognitive communication terminal apparatus 40.

  Next, transmission pattern 2 will be described using subframe 21 to subframe 24 in FIG. Transmission pattern 2 is a case where resources available for transferring 4G data signals are used for both transferring 4G data signals and transmitting cognitive radio systems. First, in subframe 21, 4G base station apparatus 20 transmits 4G control signal 513b and 4G data signal 513a to small base station apparatus 100 (step ST503). Here, the resource 513c is a free resource.

  In subframes 22 and 23 (not shown), the small base station device 100 reads the 4G control signal 513b received in the subframe 21 from the 4G base station device 20 in the data decoding unit 106, and the 4G data in the error correction decoding unit 105. The signal 513b is decoded. After that, the small base station apparatus 100 checks free resources when the 4G data signal is transferred in the cognitive control unit 114. As a result, the cognitive control unit 114 detects the free resource 514c and determines that transmission of the cognitive radio system is possible. In the small base station apparatus 100, the cognitive transmission data generation unit 115 uses the 4G control signal 514 b addressed to the 4G communication terminal apparatus 30, the 4G data signal 514 a for transfer, and the cognitive transmission signal 515 addressed to the cognitive communication terminal apparatus 40. And generate Here, the cognitive transmission signal 515 is generated as much as it can be transmitted by the free resource 514c, and includes a cognitive control signal and a data signal.

  In subframe 24, small base station apparatus 100 transfers 4G control signal 514b addressed to 4G communication terminal apparatus 30 and 4G data signal 514a for transfer to 4G communication terminal apparatus 30 (step ST504). At the same time, small base station apparatus 100 transmits cognitive transmission signal 515 to cognitive communication terminal apparatus 40 (step ST505).

  Next, transmission pattern 3 will be described using subframes 31 to 34 in FIG. Transmission pattern 3 is a case where no resource is used for transferring the 4G data signal. In the subframe 31, the 4G base station apparatus 20 does not transmit to the small base station apparatus 100. Therefore, the resource 516c is a free resource.

  In subframes 32 and 33 (not shown), the small base station apparatus 100 does not receive a signal from the 4G base station apparatus 20 in the cognitive control unit 114, and therefore determines that all resources for transferring the 4G data signal are free resources. To do. Then, the small base station apparatus 100 generates the cognitive transmission signal 517 addressed to the cognitive communication terminal apparatus 40 by the cognitive transmission data generation unit 115 as much as it can be transmitted with the free resource. Here, the cognitive transmission signal 517 includes a cognitive control signal and a data signal.

  In subframe 34, small base station apparatus 100 transmits cognitive transmission signal 517 only to cognitive communication terminal apparatus 40 (step ST506).

  Thereafter, any one of the transmission patterns of pattern 1, pattern 2, or pattern 3 is repeated in subframe units. As described above, the vacant resource is determined according to the data transfer amount between the small base station apparatus 100 and the 4G communication terminal apparatus 30, and the communication is performed using any one of the transmission patterns of the above pattern 1, pattern 2, and pattern 3. By performing the above, it is possible to perform cognitive communication with a simple method without searching for a complex free resource without causing interference to the 4G wireless system.

<Operation of each device in uplink>
The operation in the uplink of each device in Embodiment 1 of the present invention will be described using FIG. FIG. 6 is a sequence diagram showing an operation in the uplink of each device in the present embodiment.

  First, small base station apparatus 100 receives an uplink data signal of a 4G wireless system from 4G communication terminal apparatus 30 (step ST601).

  Further, when the cognitive communication terminal apparatus 40 performs uplink transmission, the small base station apparatus 100 receives an uplink data signal of the cognitive radio system from the cognitive communication terminal apparatus 40 (step ST602).

  Next, small base station apparatus 100 confirms cognitive uplink scheduling information determined at the time of downlink transmission to cognitive communication terminal apparatus 40 in cognitive control section 114 (step ST603).

  Next, the small base station apparatus 100 determines whether there is reception from the cognitive communication terminal apparatus 40 (step ST604).

  When there is reception from the cognitive communication terminal apparatus 40 (step ST604: YES), the small base station apparatus 100 performs reception processing of data received from the cognitive communication terminal apparatus 40 (step ST605).

  Next, the small base station apparatus 100 performs reception processing of the uplink data signal of the 4G wireless system from the 4G communication terminal apparatus 30 (step ST606).

Next, the small base station apparatus 100 periodically receives a known signal transmitted from the 4G communication terminal apparatus 30, and the data decryption unit 127 performs an uplink between the 4G communication terminal apparatus 30 and the small base station apparatus 100. Link 4G uplink quality information is generated (step ST607). Here, the known signal is, for example, a reference signal, a broadcast channel, or a synchronization signal.
Next, small base station apparatus 100 starts uplink data transfer to 4G base station apparatus 20 (step ST608).

  On the other hand, in step ST603, when there is no reception from the cognitive communication terminal apparatus 40 (step ST604: NO), the small base station apparatus 100 skips the process of step ST605 and performs the process after step ST606.

<Uplink signal transmission and reception method>
An uplink signal transmission / reception method according to Embodiment 1 of the present invention will be described with reference to FIGS. FIG. 7 is a diagram illustrating uplink signal transmission timing when only data transmission of the 4G wireless system in the present embodiment is performed. FIG. 8 is a diagram illustrating uplink signal transmission timings when both data transmission of the 4G radio system and data transmission of the cognitive radio system are performed in the present embodiment.

  First, uplink signal transmission timing when only data transmission of the 4G wireless system is performed will be described with reference to FIG. In this case, the small base station apparatus 100 performs only transfer of 4G data signals from the 4G communication terminal apparatus 30 to the 4G base station apparatus 20. The transfer by the small base station apparatus 100 is performed in units of subframes similarly to the downlink. In FIG. 7, there are two timings, a timing at which the 4G communication terminal apparatus 30 transmits to the small base station apparatus 100 and a timing at which the small base station apparatus 100 transmits to the 4G base station apparatus 20. Here, each timing unit is a subframe. One subframe signal is composed of a 4G data signal 711. Since the data size information of the 4G data signal 711, information for demodulating and decoding the 4G data signal 711, resource allocation information, transfer destination information, and the like are all managed by the small base station apparatus 100, in the uplink, the control signal is Do not send.

  In the small base station apparatus 100, the error correction decoding unit 126 decodes the data signal from the 4G communication terminal apparatus 30 using the 4G terminal transmission uplink scheduling information managed by the transfer control unit 107, and the 4G base station apparatus 20 A 4G data signal for transfer to is generated. For this reason, a delay occurs in the transfer by this processing. Therefore, the transfer to the 4G base station apparatus 20 is performed after the second subframe from the subframe in which the 4G data signal is received from the 4G communication terminal apparatus 30.

  In FIG. 7, it is assumed that the delay for transfer is smaller than 2 subframes.

  In subframe 41, 4G communication terminal apparatus 30 transmits 4G data signal 711 addressed to 4G base station apparatus 20 to small base station apparatus 100 (step ST701).

  In subframes 42 and 43, the small base station apparatus 100 decodes the 4G data signal 711 received from the 4G communication terminal apparatus 30 in the error correction decoding unit 126 based on the decoding information.

  Further, in the subframe 42, the small base station apparatus 100 transfers the 4G data signal received from the 4G communication terminal apparatus 30 to the 4G base station apparatus 20 in the subframe 39 (not shown) before the subframe 41 ( Step ST702).

  In subframe 43, small base station apparatus 100 receives a 4G data signal newly transmitted from 4G communication terminal apparatus 30 (step ST703).

  In subframe 44, small base station apparatus 100 transfers 4G data signal 712 for transfer addressed to 4G base station apparatus 20 generated in subframes 42 and 43 to 4G base station apparatus 20 (step ST704). .

  Thereafter, this process is repeated for each subframe. As described above, the wireless communication between the 4G communication terminal device 30 and the small base station device 100 and the wireless communication between the small base station device 100 and the 4G base station device 20 are performed at different times. Interference does not occur even when operating at the same frequency. Furthermore, since the small base station device 100 does not need to process transmission and reception at the same time, it does not receive the transmitted signal itself.

  Next, the transmission timing of the uplink signal when performing both data transmission of the 4G radio system and data transmission of the cognitive radio system will be described with reference to FIG.

  In this case, the small base station apparatus 100 receives the cognitive radio system from the cognitive communication terminal apparatus 40 in addition to the transfer of the 4G data signal from the 4G communication terminal apparatus 30 to the 4G base station apparatus 20. Here, the basic transfer timing and frame format are the same as those in FIG. In the transmission of the cognitive radio system in the cognitive communication terminal apparatus 40, the resources that can be allocated are variable according to the amount of communication between the 4G communication terminal apparatus 30 and the small base station apparatus 100. Conceivable.

  Transmission pattern 1 will be described using subframes 51 to 54 in FIG. Transmission pattern 1 is a case where all resources are used for transmission of data signals in the 4G wireless system. In subframe 51, 4G communication terminal apparatus 30 transmits 4G data signal 811 addressed to 4G base station apparatus 20 to small base station apparatus 100 (step ST801). At this time, 4G data signal 811 is transmitted using all resources available for uplink transmission based on 4G terminal transmission uplink scheduling information received from small base station apparatus 100 in the downlink. Further, the cognitive communication terminal apparatus 40 does not perform transmission based on the cognitive uplink scheduling information received from the small base station apparatus 100 on the downlink.

  In subframes 52 and 53 (not shown), the small base station apparatus 100 receives 4G data received in the subframe 51 from the 4G communication terminal apparatus 30 based on the decoding information managed by the transfer control unit 107 in the error correction decoding unit 126. The signal 801 is decoded, and a 4G data signal 812 for transfer addressed to the 4G base station apparatus 20 is generated. Here, the 4G data signal 812 is generated based on uplink scheduling information received from the 4G base station apparatus 20 on the downlink.

  In subframe 54, small base station apparatus 100 transfers 4G data signal 812 for transfer addressed to 4G base station apparatus 20 to 4G base station apparatus 20 (step ST802).

  Next, transmission pattern 2 will be described using subframe 61 to subframe 64 in FIG. The transmission pattern 2 is a case where resources available for terminal transmission are used for both transmission from the 4G communication terminal apparatus 30 and transmission from the cognitive communication terminal apparatus 40.

  First, in subframe 61, 4G communication terminal apparatus 30 transmits 4G data signal 813 addressed to 4G base station apparatus 20 to small base station apparatus 100 (step ST803).

  In addition, cognitive communication terminal apparatus 40 transmits cognitive data signal 814 to small base station apparatus 100 at the same time (step ST804). At this time, the 4G data signal 813 addressed to the 4G base station apparatus 20 is transmitted using a part of the specified resources based on the uplink scheduling information for 4G terminal transmission received from the small base station apparatus 100 in the downlink. Is done. Also, the cognitive data signal 814 is transmitted using a part of the specified resource based on the cognitive uplink scheduling information received by the cognitive communication terminal apparatus 40 in the downlink from the small base station apparatus 100.

  In subframes 62 and 63 (not shown), the small base station apparatus 100 performs 4G data signal reception processing based on 4G terminal transmission uplink scheduling information managed by the transfer control unit 107 and also manages it by the cognitive control unit 114. Cognitive data signal reception processing is performed based on the cognitive uplink scheduling information. Then, the small base station apparatus 100 decodes the 4G data signal 813 received in the subframe 61 from the 4G communication terminal apparatus 30 and generates a 4G data signal 815 for transfer addressed to the 4G base station apparatus 20. Here, the 4G data signal 815 is generated based on uplink scheduling information received from the 4G base station apparatus 20 on the downlink.

  In subframe 64, small base station apparatus 100 transfers 4G data signal 815 for transfer addressed to 4G base station apparatus 20 to 4G base station apparatus 20 (step ST805).

  Next, transmission pattern 3 will be described using subframes 71 to 74 in FIG. The transmission pattern 3 is a case where no resource is used for transmission of the 4G communication terminal device 30. In subframe 71, cognitive communication terminal apparatus 40 transmits cognitive data signal 816 to small base station apparatus 100 (step ST806). At this time, the cognitive data signal 816 is originally a resource prepared for transmission of the 4G communication terminal apparatus 30 based on the cognitive uplink scheduling information received by the cognitive communication terminal apparatus 40 on the downlink from the small base station apparatus 100. Will be sent using all of. Also, the 4G communication terminal apparatus 30 does not perform transmission based on the uplink scheduling information for 4G terminal transmission received from the small base station apparatus 100 on the downlink.

  In subframes 72 and 73 (not shown), the small base station apparatus 100 performs only cognitive data signal reception processing based on the cognitive uplink scheduling information managed by the cognitive control unit 114. Therefore, the small base station apparatus 100 does not generate a 4G data signal for transfer addressed to the 4G base station apparatus 20.

  In the subframe 74, the small base station apparatus 100 does not transmit because there is no 4G data signal for transfer addressed to the 4G base station apparatus 20.

  Thereafter, any one of the transmission patterns of pattern 1, pattern 2, or pattern 3 is repeated in subframe units. As described above, the vacant resource is determined according to the communication amount between the 4G communication terminal apparatus 30 and the small base station apparatus 100, and communication is performed using any one of the transmission patterns of the above pattern 1, pattern 2, and pattern 3. Thus, cognitive communication can be performed by a simple method without performing complicated free resource search without causing interference to the 4G wireless system.

<Effects of the present embodiment>
According to the present embodiment, free resources can be reliably detected without searching for free resources, and interference between wireless systems due to failure to search for free resources can be avoided.

(Embodiment 2)
The configuration of the communication system according to the second embodiment of the present invention is the same as that of FIG.

<Configuration of small base station device>
The configuration of small base station apparatus 900 according to Embodiment 2 of the present invention will be described using FIG. FIG. 9 is a block diagram showing a configuration of small base station apparatus 900 according to the present embodiment.

  A small base station apparatus 900 shown in FIG. 9 adds a data decoding unit 902 to the small base station apparatus 100 according to Embodiment 1 shown in FIG. 2 and a resource demapping unit instead of the resource demapping unit 123 901 and a cognitive control unit 903 instead of the cognitive control unit 114. In FIG. 9, parts having the same configuration as in FIG.

  Cognitive transmission data generation unit 115, error correction coding unit 116, data modulation unit 117, resource mapping unit 118, RF unit 119, antenna 120, antenna 121, RF unit 122, IDFT unit 134, data demodulation unit 135, error correction decoding The unit 136 and the resource demapping unit 901 constitute a communication unit that performs communication in the cognitive radio system.

  The small base station apparatus 900 includes a downlink processing unit 170 and an uplink processing unit 980. The uplink processing unit 980 performs transfer of the 4G wireless system in the uplink or communication of the cognitive wireless system in the uplink.

  The transfer control unit 107 outputs the 4G downlink scheduling information for small base station transmission and the uplink scheduling information for 4G terminal transmission to the transfer data generation unit 108 and the cognitive control unit 903. Since the configuration of the transfer control unit 107 other than the above is the same as that of the first embodiment, the description thereof is omitted.

  The RF unit 122 down-converts the received signal input from the antenna 121 and performs synchronization processing. Thereafter, the RF unit 122 removes the guard interval from the received signal, performs fast Fourier transform on the received signal, and outputs the result to the resource demapping unit 901.

  The resource demapping unit 901 extracts a known signal periodically transmitted from the cognitive communication terminal device 40 from the received signal input from the RF unit 122, and outputs the extracted known signal to the data decoding unit 902. Note that the configuration of the resource demapping unit 901 other than the above is the same as that of the resource demapping unit 123, and thus the description thereof is omitted.

  The IDFT unit 134 performs discrete inverse Fourier transform on the data signal input from the resource demapping unit 901 and outputs the result to the data demodulation unit 135.

  Data demodulation section 135 demodulates the data signal input from IDFT section 134 based on the demodulation information input from cognitive control section 903, and outputs the demodulated signal to error correction decoding section 136.

  The error correction decoding unit 136 performs error correction decoding on the demodulated signal input from the data demodulation unit 135 based on the decoding information input from the cognitive control unit 903, and outputs the decoded data to the data decoding unit 902.

  The data decoding unit 902 obtains cognitive uplink quality information by measuring the uplink channel quality between the cognitive communication terminal device 40 and the small base station device 900 from the known signal input from the resource demapping unit 901. The acquired cognitive uplink quality information is output to the cognitive control unit 903.

  The data decoding unit 902 extracts downlink cognitive downlink quality information between the small base station device 900 and the cognitive communication terminal device 40 from the decoded data input from the error correction decoding unit 136. The data decoding unit 902 outputs the extracted cognitive downlink quality information to the cognitive control unit 903.

  The cognitive control unit 903 uses the cognitive downlink quality information input from the data decoding unit 902 to perform downlink scheduling of the cognitive radio system. Specifically, the cognitive control unit 903 refers to the cognitive downlink quality information when there is an available resource from the small base station transmission 4G downlink scheduling information input from the transfer control unit 107, and refers to the cognitive downlink quality information. The resource used for transmission of the cognitive radio system is allocated to a place with good quality. For example, the cognitive control unit 903 allocates resources used for transmission in the cognitive radio system to resources whose channel quality indicated by the channel quality information is equal to or higher than a threshold value.

  The cognitive control unit 903 determines the coding rate and the modulation multi-level number when transmitting the cognitive radio system based on the cognitive downlink quality information and the transmission data size.

  The cognitive control unit 903 performs uplink scheduling of the cognitive radio system using the cognitive uplink quality information input from the data decoding unit 902. Specifically, the cognitive control unit 903 refers to the cognitive uplink quality information when there is a free resource for transfer from the uplink scheduling information for 4G terminal transmission input from the transfer control unit 107, and determines the channel quality. Allocation of resources used for reception of the cognitive radio system is performed in a good place. For example, the cognitive control unit 903 allocates resources used for reception of the cognitive radio system to resources whose channel quality indicated by the channel quality information is equal to or higher than a threshold value.

  The cognitive control unit 903 determines the coding rate and the modulation multi-level number for transmission based on the cognitive uplink quality information and the scheduled reception data size.

  During the downlink operation of the cognitive radio system, the cognitive control unit 903 outputs the encoded information in the downlink of the cognitive radio system to the error correction encoding unit 116, outputs the modulation information to the data modulation unit 117, and allocates resources. Information is output to the resource mapping unit 118.

  The cognitive control unit 903 outputs resource allocation information in the uplink of the cognitive radio system to the resource demapping unit 901 during the uplink operation of the cognitive radio system. Further, the cognitive control unit 903 activates the cognitive reception function unit 960, outputs demodulation information to the data demodulation unit 135, and outputs decoded information to the error correction decoding unit 136.

  The configuration other than the above in the cognitive control unit 903 is the same as that of the cognitive control unit 114, and thus the description thereof is omitted.

  The cognitive transmission data generation unit 115 generates cognitive transmission control information based on the cognitive downlink scheduling information or the cognitive uplink scheduling information input from the cognitive control unit 903. The cognitive transmission data generation unit 115 outputs the generated control information and the payload data input from the cognitive control unit 903 to the error correction encoding unit 116.

  Based on the encoded information input from the cognitive control unit 903, the error correction encoding unit 116 performs error correction encoding on the control information and payload data input from the cognitive transmission data generation unit 115, and converts the encoded data into The data is output to the data modulation unit 117.

  Data modulation section 117 modulates the encoded data input from error correction encoding section 116 based on the modulation information input from cognitive control section 903, and outputs the modulated signal to resource mapping section 118.

  Based on the resource allocation information input from the cognitive control unit 903, the resource mapping unit 118 maps the modulation signal input from the data modulation unit 117 to an appropriate frequency and an appropriate time, and outputs the mapped signal to the RF unit 119.

<Operation of each device in downlink>
Operations in the downlink of each device in Embodiment 2 of the present invention will be described using FIG. FIG. 10 is a sequence diagram showing an operation in the downlink of each device in the present embodiment. 10, parts that are the same as those in FIG. 3 are given the same reference numerals, and descriptions thereof are omitted.

  After step ST301, the small base station apparatus 900 receives the cognitive downlink quality information from the cognitive communication terminal apparatus 40 (step ST1001).

  Further, after step ST1001, the small base station apparatus 900 receives a downlink data signal from the 4G base station apparatus 20 (step ST302).

  In step ST309, when the cognitive control unit 903 determines that cognitive transmission is possible because there is a free resource (step ST309: YES), the cognitive control unit 903 performs downlink and uplink scheduling of the cognitive radio system using the free resource. (Step ST1002).

  Specifically, the cognitive control unit 903 allocates free resources for downlink transmission to the cognitive communication terminal apparatus 40 and uplink reception from the cognitive communication terminal apparatus 40. In downlink scheduling, the cognitive control unit 903 has good channel quality in which the channel quality of the cognitive downlink quality information received in step ST1001 is greater than or equal to the threshold among the free resources for downlink transfer in the 4G wireless system. Resource allocation is performed for various frequencies and times. Also, the cognitive control unit 903 determines the coding rate and the modulation multi-level number based on the cognitive downlink quality information and the transmission data size. In uplink scheduling, the data decoding unit 902 measures uplink channel quality between the cognitive communication terminal device 40 and the small base station device 900 and generates cognitive uplink quality information. The cognitive control unit 903 performs resource allocation for a frequency and time with good channel quality in which the channel quality of the cognitive uplink quality information is equal to or higher than a threshold value in the free resources for 4G uplink transmission. Also, the cognitive control unit 903 determines a coding rate and a modulation multi-level number for transmission based on the cognitive uplink quality information and the scheduled reception data size.

  Next, small base station apparatus 900 adds cognitive downlink scheduling information and cognitive uplink scheduling information determined in step ST1002 to cognitive transmission data in cognitive transmission data generation section 115 (step ST311).

<Operation of each device in uplink>
The operation in the uplink of each device in Embodiment 2 of the present invention will be described using FIG. FIG. 11 is a sequence diagram showing operations in the uplink of each device in the present embodiment. In FIG. 11, parts that are the same as those in FIG. 6 are given the same reference numerals, and descriptions thereof are omitted.

  After step ST605, small base station apparatus 900 uses cognitive uplink quality between cognitive communication terminal apparatus 40 and small base station apparatus 900 based on a known signal transmitted from cognitive communication terminal apparatus 40 in data decoding section 902. Information is generated (step ST1101).

  Next, small base station apparatus 900 performs reception processing for uplink data of the 4G wireless system from 4G communication terminal apparatus 30 (step ST606).

  On the other hand, in step ST603, when there is no reception from the cognitive communication terminal apparatus 40 (step ST604: NO), the small base station apparatus 900 skips the processes of step ST605 and step ST1101, and performs the processes after step ST606. I do.

  Note that the downlink signal transmission / reception method and uplink signal transmission / reception method in the present embodiment are the same as those in the first embodiment, and a description thereof will be omitted.

<Effects of the present embodiment>
According to the present embodiment, in addition to the effects of the first embodiment, since free resources are allocated in consideration of channel quality when transmitting and receiving in the cognitive radio system, communication quality in the cognitive radio system is improved. be able to.

<Modification common to all embodiments>
In the first embodiment and the second embodiment, the terminal that needs to be transferred by the small base station apparatus is a 4G communication terminal apparatus. However, the present invention is not limited to this and may be an LTE compatible terminal.

  Moreover, in the said Embodiment 1 and Embodiment 2, although the 4G communication terminal device and the cognitive communication terminal device were each one, this invention is not restricted to this, A plurality may be sufficient respectively.

  Further, in the first embodiment and the second embodiment, when scheduling the 4G radio system and the cognitive radio system, the resource allocation of the 4G radio system and the cognitive radio system is determined from the past resource utilization rate, The trouble of scheduling may be omitted.

  Also, in the first embodiment and the second embodiment, the transfer processing between the small base station apparatus and the 4G communication terminal apparatus is performed by spatial multiplexing, so that free resources at the time of transfer are increased and used for cognitive transmission. May be.

  Moreover, in Embodiment 1 and Embodiment 2 described above, the transfer is performed by the small base station apparatus. However, the present invention is not limited to this, and the transfer is performed using any communication apparatus other than the small base station apparatus, for example, a relay node. be able to.

  The communication apparatus and the communication method according to the present invention are suitable for performing communication between a cognitive radio system and a radio system other than the cognitive radio system, for example.

100 Small base station apparatus 101, 113, 120, 121, 133 Antenna 102, 112, 119, 122, 132 RF unit 103, 123 Resource demapping unit 104, 125, 135 Data demodulation unit 105, 126, 136 Error correction decoding unit 106, 127 Data decoding unit 107 Transfer control unit 108 Transfer data generation unit 109, 116, 128 Error correction encoding unit 110, 117, 129 Data modulation unit 111, 118, 131 Resource mapping unit 114 Cognitive control unit 115 Cognitive transmission data generation Unit 124, 134 IDFT unit 130 DFT unit 150 cognitive transmission function unit 160 cognitive reception function unit 170 downlink processing unit 180 uplink processing unit

Claims (3)

A communication device that operates as a relay device of the first communication method and operates as a base station device of the second communication method,
Transfer means for transferring data in communication using the first communication method;
A communication means for performing communication of the second communication method;
When performing the transfer, control is performed so that the scheduling for the transfer is performed based on the channel quality with the transfer destination, and the communication of the second communication method is performed using the free resources generated by the scheduling. Control means to
A communication apparatus comprising: Further comprising line quality information acquisition means for acquiring line quality information with a communication partner according to the second communication method;
The control means includes
The communication apparatus according to claim 1, wherein control is performed such that communication using the second communication method is performed using the free resource having a line quality indicated by the line quality information equal to or higher than a predetermined quality. A communication method in a communication device that operates as a relay device of the first communication method and operates as a base station device of the second communication method,
Transferring data in communication using the first communication method;
Performing communication of the second communication method;
When performing the transfer, control is performed so that the scheduling for the transfer is performed based on the channel quality with the transfer destination, and the communication of the second communication method is performed using the free resources generated by the scheduling. And steps to
A communication method comprising:

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