WO2010016272A1 - 基地局、及び、端末 - Google Patents
基地局、及び、端末 Download PDFInfo
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- WO2010016272A1 WO2010016272A1 PCT/JP2009/003800 JP2009003800W WO2010016272A1 WO 2010016272 A1 WO2010016272 A1 WO 2010016272A1 JP 2009003800 W JP2009003800 W JP 2009003800W WO 2010016272 A1 WO2010016272 A1 WO 2010016272A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0053—Allocation of signaling, i.e. of overhead other than pilot signals
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0001—Arrangements for dividing the transmission path
- H04L5/0003—Two-dimensional division
- H04L5/0005—Time-frequency
- H04L5/0007—Time-frequency the frequencies being orthogonal, e.g. OFDM(A), DMT
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/50—Allocation or scheduling criteria for wireless resources
- H04W72/51—Allocation or scheduling criteria for wireless resources based on terminal or device properties
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/23—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
Definitions
- the present invention relates to a base station and a terminal.
- SC-FDMA Single-Carrier Frequency Division Multiple Access
- N symbols on the time axis modulated by a predetermined modulation scheme for example, QPSK
- QPSK a predetermined modulation scheme
- An SC-FDMA symbol is formed by adding CP (Cyclic Prefix) after returning to the waveform. That is, one SC-FDMA symbol includes N time continuous signals and CP.
- a radio communication base station apparatus (hereinafter sometimes simply referred to as “base station”) is connected to a radio communication terminal apparatus (hereinafter also simply referred to as “terminal”) with respect to a physical channel (for example, an uplink data line resource is allocated through PDCCH (Physical Downlink Control Channel).
- base station a radio communication base station apparatus
- terminal a radio communication terminal apparatus
- PDCCH Physical Downlink Control Channel
- the terminal When the terminal receives the allocation information of the uplink data line resource from the base station, the terminal transmits the data accumulated in the buffer of the terminal to the base station using the resource.
- ARQ Automatic Repeat Request
- the terminal feeds back a response signal indicating an error detection result of downlink data to the base station.
- CRC Cyclic Redundancy Check
- ACK Acknowledgment
- NACK Negative Acknowledgment
- CRC NG
- PUCCH Physical Uplink Control Channel
- FIG. 1 is a diagram showing a PUCCH resource allocation when the system bandwidth in a 3GPP LTE system (hereinafter sometimes referred to as “LTE system”) is 20 MHz.
- PUSCH Physical Uplink Shared Channel
- FIG. 1 is used for uplink data transmission of the terminal.
- time is divided into subframe units.
- Each subframe has two slots.
- One slot includes seven SC-FDMA symbols.
- the PUCCH is arranged at both ends of the system band, specifically, resource blocks (RB: Resource Block) at both ends of the system band. PUCCHs arranged at both ends of the system band are interchanged between slots, that is, frequency hopped for each slot.
- LTE terminal A terminal compatible with 3GPP LTE system (hereinafter sometimes referred to as “LTE terminal”), for example, when PUCCH1 in FIG. 1 is assigned, a response signal or the like is sent to PUCCH1 in which the system band edge arranged for each slot is replaced. Map the control channel signal. At this time, the control channel signal is mapped so as to be temporally continuous at the boundary of two slots included in the same subframe.
- the LTE terminal matches the center frequency of its own transmission band (that is, transmission RF frequency) with the center frequency of the 20 MHz system band, and can support the entire 20 MHz band.
- a control channel signal is generated digitally using a circuit. Specifically, in the IFFT circuit of the LTE terminal, in the previous slot in a certain subframe, the control channel signal is input only to the RB having the frequency at the upper end of the system band, and 0 is input to the other frequency components. . In the IFFT circuit of the LTE terminal, in the subsequent slot in the same subframe, the control channel signal is input only to the RB having the lower frequency of the system band, and 0 is input to the other frequency components.
- a terminal having an RF circuit corresponding to a 20 MHz bandwidth can continuously create a control channel signal for frequency hopping.
- LTE + system The 3GPP LTE-advanced system (hereinafter sometimes referred to as “LTE + system”) follows the LTE system.
- LTE + system it is expected that base stations and terminals capable of communicating at a broadband frequency of 20 MHz or higher will be introduced in order to realize a downlink transmission speed of 1 Gbps or higher.
- terminal capability Capability
- the minimum value of the support bandwidth is 20 MHz.
- an LTE + system compatible base station (hereinafter sometimes referred to as “LTE + base station”) is configured to be able to communicate in a frequency band including a plurality of “unit bands”.
- the “unit band” in the downlink is a band having a maximum width of 20 MHz and including SCH (Synchronization Channel) near the center, and is defined as a basic unit of the communication band. Further, it may be defined as a band defined by downlink frequency band information in BCH (Broadcast Channel) broadcast from a base station, or a band defined by a dispersion width when PDCCHs are dispersedly arranged. is there.
- BCH Broadcast Channel
- the “unit band” in the uplink is a band delimited by the uplink frequency band information in the BCH broadcast from the base station, or a frequency base of 20 MHz or less including PUSCH near the center and including PUCCH at both ends. Defined as a unit. Furthermore, the LTE terminal can receive only one “unit band” at a time and can transmit only one “unit band” at a time. In addition, the “unit band” may be expressed as “Component Carrier (s)” in English in 3GPP LTE-Advanced.
- the LTE + base station needs to support not only the LTE terminal but also an LTE + system compatible terminal (hereinafter also referred to as “LTE + terminal”).
- LTE + terminal includes a terminal capable of accommodating only one unit band with communicable bandwidth and a plurality of unit bands with communicable bandwidth. Possible terminals.
- an integrated communication system including an LTE system that assigns an independent single communication for each unit band and an LTE + system that follows the LTE system and can assign a plurality of unit bands to a single communication is actually operated. Will be. *
- the LTE terminal and the LTE + terminal need to transmit a control channel signal to the base station.
- the uplink system band is divided into two unit bands of 20 MHz, and PUCCH is frequency hopped within each unit band. That is, the terminals are divided into two groups, and terminals belonging to one group transmit response signals in the high frequency side unit band, and terminals belonging to the other group transmit response signals in the low frequency side unit band. To do. By doing so, PUCCH for response signal transmission can be secured while coexisting LTE terminals and LTE + terminals that support only 20 MHz and LTE + terminals that support 40 MHz.
- the 40 MHz uplink system band is divided by the PUCCH. That is, PUSCH is divided by PUCCH. Therefore, it is impossible to apply to two PUSCHs in which the SC-FDMA scheme that can transmit signals only in the continuous band is divided. Therefore, even a terminal that can support 40 MHz cannot exhibit a transmission rate according to the terminal capability.
- An object of the present invention is to provide a base station and a terminal that realize a control channel arrangement method in a frame that can be used by terminals having various terminal capabilities while realizing broadband uplink data communication. is there.
- the base station of the present invention is a base station capable of assigning a plurality of unit bands to a single communication, and has a configuration pattern of an uplink subframe composed of 2 slots, and control channels at both ends of each unit band.
- Channel blocks including a plurality of control channels are arranged at both ends of a first pattern in which the control channels arranged at both ends of each unit band are exchanged between slots and an extension band composed of a plurality of unit bands.
- Information on the selected configuration pattern for the allocation target terminal to which the uplink subframe is allocated, and selecting means for selecting from a second pattern in which the frequency position of the configuration control channel is switched between slots in each control channel block Transmitting means for transmitting Take the deposition.
- a terminal according to the present invention is a terminal that is assigned by a base station that can assign a plurality of unit bands to a single communication and that transmits an SC-FDMA symbol in an uplink subframe consisting of two slots.
- the configuration pattern of the subframe is a first pattern in which control channels are arranged at both ends of each unit band and the control channels arranged at both ends of each unit band are interchanged between slots, or a plurality of units
- Pattern information indicating whether or not channel blocks including a plurality of control channels are arranged at both ends of an extension band composed of bands and the frequency position of the configuration control channel in each channel block is a second pattern interchanged between slots.
- a transmission means configured to transmit the SC-FDMA symbol; and a means for forming the SC-FDMA symbol, wherein the control channel signal is mapped to a frequency position corresponding to the pattern information in the SC-FDMA symbol.
- the control band is matched with one end of the extension band and the control channel is arranged in the channel block arranged at the one end.
- the vector employs a configuration comprising a control means for changing in the front slot and rear slot, the.
- a terminal according to the present invention is a terminal that is assigned by a base station that can assign a plurality of unit bands to a single communication and that transmits an SC-FDMA symbol in an uplink subframe consisting of two slots.
- the configuration pattern of the subframe is a first pattern in which control channels are arranged at both ends of each unit band and the control channels arranged at both ends of each unit band are interchanged between slots, or a plurality of units
- Pattern information indicating whether or not channel blocks including a plurality of control channels are arranged at both ends of an extension band composed of bands and the frequency position of the configuration control channel in each channel block is a second pattern interchanged between slots.
- a transmission means configured to transmit the SC-FDMA symbol via a plurality of antennas; and a means for forming the SC-FDMA symbol, wherein a control channel signal is transmitted in accordance with the pattern information in the SC-FDMA symbol.
- Forming means including mapping means for mapping to a frequency position; and the acquired pattern information indicates the second pattern, and the basic bandwidth of the configuration pattern corresponding to the pattern information is more than the communicable bandwidth of the own device.
- the present invention it is possible to provide a base station and a terminal that realize a control channel arrangement method in a frame that can be used by terminals having various terminal capabilities while realizing broadband uplink data communication. it can.
- the figure which shows the condition of the uplink frame based on the scheduling of the sub-frame structure pattern by a base station The figure which uses for description of the transmission operation
- the figure which shows the condition of the uplink frame based on the scheduling of the sub-frame structure pattern by a base station The figure which uses for description of the transmission operation
- the figure which shows the condition of the uplink frame based on the scheduling of the sub-frame structure pattern by a base station The figure which uses for description of the transmission operation
- movement of the response signal by a terminal when the communicable bandwidth and the basic bandwidth of a 2nd pattern are equal
- FIG. 3 is a block diagram showing a configuration of terminal 100 according to Embodiment 1 of the present invention.
- a terminal 100 includes a reception RF unit 105, an OFDM signal demodulation unit 110, a signal synthesis unit 115, a separation unit 120, a broadcast signal reception unit 125, a PDCCH reception unit 130, and a PDSCH (Physical Downlink Shared).
- the terminal 100 Since the terminal 100 has two antennas, the terminal 100 includes two reception RF units 105, two OFDM signal demodulation units 110, and two transmission RF units 185, respectively. That is, since the terminal 100 includes two transmission RF units 185, the terminal 100 includes two power amplifiers (PA).
- PA power amplifier
- the reception RF unit 105 performs reception radio processing (down-conversion, analog digital (A / D) conversion, etc.) on the reception radio signal received via the antenna, and the obtained reception signal is sent to the OFDM signal demodulation unit 110. Output.
- reception radio processing down-conversion, analog digital (A / D) conversion, etc.
- the OFDM signal demodulation unit 110 includes CP (Cyclic Prefix) removal units 111-1 and 111-2 and fast Fourier transform (FFT) units 112-1 and 112-2.
- the OFDM signal demodulation unit 110 receives the received OFDM signal from each of the reception RF units 105-1 and 105-1.
- CP removal sections 111-1 and 2 remove the CP from the received OFDM signal
- FFT sections 112-1 and 2 convert the received OFDM signal after the CP removal into a frequency domain signal. This frequency domain signal is output to the signal synthesis unit 115.
- the signal synthesizer 115 synthesizes the frequency domain signals obtained by the FFT units 112-1 and 2 for each frequency component.
- the separation unit 120 separates the frequency domain signal received from the signal synthesis unit 115 into a notification signal, a control signal (that is, a PDCCH signal), and a data signal (that is, a PDSCH signal) included therein.
- the broadcast signal is output to broadcast signal receiver 125, the PDCCH signal is output to PDCCH receiver 130, and the PDSCH signal is output to PDSCH receiver 135.
- the notification signal receiving unit 125 extracts the PUCCH arrangement information included in the notification signal received from the separation unit 120, and outputs the extracted PUCCH arrangement information to the control unit 140.
- the PDCCH reception unit 130 extracts uplink allocation information and downlink allocation information included in the control signal received from the separation unit 120, outputs the obtained uplink allocation information to the control unit 140, and transmits the downlink allocation information to the PDSCH reception unit 135. Output to.
- the PDSCH receiving unit 135 extracts the downlink data signal addressed to the own device based on the downlink assignment information received from the PDCCH receiving unit 130 (that is, the frequency position information to which the downlink data signal addressed to the own device is mapped).
- the received data signal is subjected to reception processing (demodulation processing and decoding processing), and the obtained decoding result is output to the reception error determination unit 145.
- control unit 140 Based on the uplink allocation information received from PDCCH receiving unit 130 and the PUCCH arrangement information received from broadcast signal receiving unit 125, control unit 140 maps the weighting vector used for precoding and the frequency position for mapping the response signal in the SC-FDMA signal. And control the transmission band.
- PUCCH arrangement information includes uplink subframe configuration pattern information.
- the configuration pattern of the uplink subframe includes a first pattern in which control channels are arranged at both ends of each unit band and the control channels arranged at both ends of each unit band are interchanged between slots, and a plurality of unit bands.
- the unit bandwidth is the “basic bandwidth”
- the extension bandwidth is the basic bandwidth.
- control unit 140 determines whether the configuration pattern of the uplink subframe to which the own device is assigned is the first pattern or the second pattern.
- the control unit 140 outputs a mapping control signal for mapping the PUCCH signal (that is, the response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to the SC-FDMA signal forming unit 175.
- the control unit 140 maps the response signal to one end of the IFFT frequency band in the SC-FDMA signal forming unit 175 in the previous slot of the same subframe, and in the subsequent slot, The response signal is mapped to the other end.
- control unit 140 maps the response signal to one end of the IFFT frequency band in SC-FDMA signal forming unit 175 in the previous slot and the subsequent slot of the same subframe.
- the control unit 140 causes the SC-FDMA signal forming unit 175 to map the PUCCH signal to the frequency position corresponding to the control channel assigned to the own device in the channel block arranged at one end thereof.
- control unit 140 determines the weighting vector used in the SC-FDMA signal forming unit 175 according to the precoding information between the previous slot and the subsequent slot of the same subframe. Switch.
- the communicable bandwidth (bandwidth determined by the terminal capability (Capability)) of the own device is compared with the basic bandwidth of the second pattern.
- the control unit 140 sets the spreading code used in the response signal spreading unit 165 to the normal code A spreading code for the format (Normal format) is used. At this time, the control unit 140 matches the transmission band of the transmission RF unit 185 with the extension band.
- the control unit 140 arranges the transmission band of the transmission RF unit 185 by the control channel assigned to the own device. Align with one end of the extended band. The adjustment of the transmission band is performed based on the center frequency instruction output from the control unit 140. Also at this time, the control unit 140 sets the spreading code used in the response signal spreading unit 165 as a spreading code for a normal format.
- the reception error determination unit 145 determines the success or failure of the decoding by CRC check, and outputs the result to the response signal generation unit 150.
- the response signal generation unit 150 generates a response signal (ACK or NACK) based on the signal indicating the reception success / failure received from the reception error determination unit 145, and outputs the response signal to the modulation unit 155.
- ACK response signal
- NACK response signal
- Modulation section 155 modulates the response signal received from response signal generation section 150 using a predetermined modulation scheme (BPSK, QPSK, etc.), and outputs the modulated response signal to response signal spreading section 165.
- a predetermined modulation scheme BPSK, QPSK, etc.
- Modulation section 160 modulates the input transmission data based on an instruction from control section 140 and outputs the obtained modulated data signal to switching section 170.
- Response signal spreading section 165 spreads the modulated response signal using a spreading code according to the instruction from control section 140 and outputs the spread response signal to switching section 170.
- the switching unit 170 selects either the modulated data signal or the response signal after spreading based on an instruction from the control unit 140, and outputs the selection signal to the SC-FDMA signal forming unit 175.
- the SC-FDMA signal forming unit 175 forms an SC-FDMA signal in which the output signal of the switching unit 170 is mapped to a frequency position according to an instruction from the control unit 140, and outputs the SC-FDMA signal to the transmission RF unit 185.
- SC-FDMA signal forming section 175 includes DFT section 176, frequency mapping section 177, precoding section 178, IFFT sections 179-1, 2 and CP adding sections 180-1, 2.
- the DFT unit 176 separates the input signal into a plurality of frequency components. Then, the frequency mapping unit 177 maps the signal obtained by the DFT unit 176 to the frequency position according to the instruction from the control unit 140.
- the precoding unit 178 performs precoding processing corresponding to the precoding information on the frequency domain signal in which the response signal is mapped to a predetermined frequency position by the frequency mapping unit 177.
- the precoding unit 178 precodes the frequency domain signal arranged in the previous slot of the same subframe with the first weighting vector. That is, the precoding unit 178 outputs the frequency domain signal weighted with the first element of the first weighting vector to the IFFT unit 179-1 and also outputs the frequency domain signal weighted with the second element of the first weighting vector. The data is output to IFFT unit 179-2. Further, the precoding unit 178 precodes the frequency domain signal arranged in the subsequent slot of the same subframe with the second weighting vector orthogonal to the first weighting vector.
- Precoding section 178 outputs the frequency domain signal weighted with the first element of the second weighting vector to IFFT section 179-1 and also outputs the frequency domain signal weighted with the second element of the second weighting vector to the IFFT section. Output to 179-2.
- the response signal subjected to spatial hopping can be transmitted.
- IFFT section 179-1 IFFT section 179-2
- CP adding section 180-1 CP adding section 180-2
- CP Cyclic Prefix
- the transmission RF unit 185 is configured to be able to change the transmission band.
- the transmission RF unit 185 receives the center frequency instruction from the control unit 140 and moves the transmission band by moving the RF center frequency based on the center frequency instruction.
- the transmission RF unit 185-1 performs transmission radio processing on the SC-FDMA signal received from the CP addition unit 180-1 and transmits the SC-FDMA signal via the first antenna.
- the transmission RF unit 185-2 performs transmission radio processing on the SC-FDMA signal received from the CP addition unit 180-2 and transmits the SC-FDMA signal via the second antenna.
- the center frequency of the transmission band is used as the reference frequency, any frequency included in the transmission band can be used as the reference frequency.
- FIG. 4 is a block diagram showing a configuration of base station 200 according to Embodiment 1 of the present invention.
- the base station 200 includes a modulation unit 205, a retransmission control unit 210, a modulation unit 215, a broadcast signal generation unit 220, a modulation unit 225, a multiplexing unit 230, an OFDM signal formation unit 235, and a transmission.
- An RF unit 240, a reception RF unit 245, an SC-FDMA signal demodulation unit 250, a separation unit 255, a data reception unit 260, a response signal reception unit 265, and a control unit 270 are included.
- the modulation unit 205 modulates uplink allocation information and downlink allocation information received from the control unit 270 and outputs a modulated signal to the multiplexing unit 230.
- the retransmission control unit 210 receives new transmission data, holds the new transmission data, and outputs the ACK signal related to the previous transmission data to the modulation unit 215 as a trigger. Further, when receiving a NACK signal from response signal receiving section 265, retransmission control section 210 outputs the held transmission data to modulating section 215 for retransmission.
- Modulation section 215 modulates transmission data received from retransmission control section 210 and outputs the modulated signal to multiplexing section 230.
- the notification signal generation unit 220 generates a notification signal including information indicating the configuration pattern selected by the control unit 270 and outputs the notification signal to the modulation unit 225.
- the modulation unit 225 modulates the notification signal received from the notification signal generation unit 220 and outputs the modulation signal to the multiplexing unit 230.
- the multiplexing unit 230 performs time multiplexing or frequency modulation on the transmission signal modulated signal received from the modulation unit 215, the uplink allocation information and the downlink allocation information modulation signal received from the modulation unit 205, and the broadcast signal modulation signal received from the modulation unit 225. Multiplex to form a multiplexed signal.
- the modulation signal of the transmission data is arranged in a resource corresponding to the PDSCH.
- the modulation signals for uplink allocation information and downlink allocation information are arranged in resources corresponding to PDCCH.
- the modulated signal of the broadcast signal is arranged in a resource corresponding to BCH (Broadcast channel).
- the IFFT unit 236 serial-parallel converts the multiplexed signal formed by the multiplexing unit 230, and then performs inverse fast Fourier transform to obtain a time waveform.
- the CP adding unit 237 adds a CP to this time waveform to obtain an OFDM signal.
- the transmission RF unit 240 performs transmission radio processing on the OFDM signal formed by the OFDM signal forming unit 235, and transmits it through the antenna.
- the reception RF unit 245 performs reception radio processing (down-conversion, analog digital (A / D) conversion, etc.) on the reception radio signal received via the antenna, and the obtained reception signal is an SC-FDMA signal demodulation unit. Output to 250.
- the SC-FDMA signal demodulation unit 250 demodulates the received SC-FDMA signal received from the reception RF unit 245. Specifically, CP removing section 251 removes CP from the received SC-FDMA signal, and FFT section 252 converts the received SC-FDMA signal after CP removal into a frequency domain signal. Then, the signal extraction unit 253 extracts a frequency component corresponding to the frequency allocation information received from the control unit 270 from the frequency domain signal, and the IDFT unit 254 extracts the extracted frequency component as a single carrier signal on the time axis. Convert to
- Separating section 255 separates the single carrier signal received from SC-FDMA signal demodulating section 250 into a received data signal and a response signal, outputs the received data signal to data receiving section 260, and outputs the response signal to the response signal receiving section.
- the data receiving unit 260 decodes the received data signal received from the separating unit 255 and transfers the obtained decoded data to an upper layer such as a MAC.
- the response signal receiving unit 265 performs a despreading process corresponding to the spreading process in the response signal spreading unit 165 of the terminal 100 on the response signal received from the demultiplexing unit 255, thereby transmitting the response transmitted from the terminal 100. retrieve the signal. Furthermore, the response signal receiving unit 265 combines (for example, maximum ratio combining) response signals that are repeated twice while performing frequency hopping within one subframe. Then, the response signal receiving unit 265 determines whether the response signal indicates ACK or NACK based on the composite signal, and outputs an ACK signal or a NACK signal to the retransmission control unit 210 according to the determination result. To do.
- the control unit 270 allocates uplink resources and downlink resources to the terminal 100. That is, the control unit 270 performs scheduling of uplink resources and downlink resources. Then, the control unit 270 outputs uplink allocation information and downlink allocation information, which are scheduling results, to the modulation unit 205. Control section 270 also outputs uplink allocation information (here, frequency allocation information) to SC-FDMA signal demodulation section 250.
- uplink allocation information here, frequency allocation information
- control unit 270 uses the first pattern in which the control channel is arranged at both ends of each unit band and the control channel arranged at both ends of each unit band is switched between slots. And a second block in which channel blocks including a plurality of control channels are arranged at both ends of an extension band composed of a plurality of unit bands, and the frequency positions of the constituent control channels are switched between slots in each control channel block. .
- Information indicating the selected configuration pattern is output to the notification signal generation unit 220.
- the uplink subframe configuration pattern is such that the control channels are arranged at both ends of each unit band, and the control channels arranged at both ends of each unit band are switched between slots. From the second pattern in which channel blocks including a plurality of control channels are arranged at both ends of an extension band composed of a pattern and a plurality of unit bands, and the frequency positions of the constituent control channels are switched between slots in each control channel block, Selected for each subframe. That is, base station 200 schedules subframe configuration patterns.
- FIG. 5 shows the state of the uplink frame based on the scheduling of the subframe configuration pattern by the base station.
- the base station 200 alternately selects the first pattern and the second pattern.
- the unit band has a bandwidth of 20 MHz.
- the extension band has a bandwidth corresponding to two unit bands, that is, a bandwidth of 40 MHz. That is, in the first pattern, 20 MHz is the basic bandwidth, and in the second pattern, 40 MHz is the basic bandwidth.
- Information indicating the selected configuration pattern is included in the broadcast information by the broadcast signal generation unit 220 and broadcast.
- Base station 200 basically assigns a second pattern subframe to terminal 100 capable of transmitting a response signal by spatial hopping. Further, for example, a first pattern subframe is allocated to a terminal such as an LTE terminal that cannot transmit a response signal by spatial hopping.
- a subframe having a basic bandwidth of 40 MHz (that is, the second subframe in FIG. 5) is allocated to terminal 100.
- subframes with a basic bandwidth of 20 MHz (that is, the first and third subframes in FIG. 5) are allocated to LTE terminals.
- the base station 200 assigns an uplink subframe in which a configuration pattern having a base bandwidth as wide as possible is selected to a terminal having a broadband terminal transmission capability.
- the allocation target terminal can transmit an uplink data signal at high speed on the PUSCH to which a central frequency region other than the PUCCHs at both ends (a continuous frequency band of about 30 MHz in FIG. 5) is allocated. .
- control section 140 In terminal 100, control section 140, based on uplink allocation information addressed to itself and transmitted from base station 200 and PUCCH arrangement information broadcast from base station 200, (1) weighting vector used for precoding (2) Control the frequency position for mapping the response signal in the SC-FDMA signal, and (3) Control the transmission band.
- control unit 140 determines whether the configuration pattern of the uplink subframe to which the own device is assigned is the first pattern or the second pattern.
- the control unit 140 allows the precoding unit 178 to use a weighting vector whose elements are all 1 (that is, even if the precoding unit 178 does not substantially precode). The weighting vector used may be switched between the previous slot and the subsequent slot of the same subframe.
- the control unit 140 maps the response signal to one end of the IFFT frequency band in the SC-FDMA signal forming unit 175 in the previous slot of the same subframe, and maps the response signal to the other end in the subsequent slot. .
- the control unit 140 matches the transmission band of the transmission RF unit 185 with the unit band assigned to the own device.
- the control unit 140 compares the communicable bandwidth (bandwidth determined by the terminal capability (Capability)) with the basic bandwidth of the second pattern.
- the control unit 140 sets the weighting vector used in the precoding unit 178 before the same subframe. Switch between slot and back slot. Here, the weighting vector switching timing is the boundary between the previous slot and the subsequent slot.
- the control unit 140 causes the frequency mapping unit 177 to map the PUCCH signal to the frequency position corresponding to the control channel assigned to the own device in the channel block arranged at one end.
- the control unit 140 matches the transmission band of the transmission RF unit 185 with one end of the extension band in which the control channel assigned to the own unit is arranged.
- FIG. 6 is a diagram for explaining the response signal transmission operation by the terminal 100 when the communicable bandwidth of the own device is smaller than the basic bandwidth of the second pattern.
- terminal 100 having a transmittable bandwidth of 20 MHz and an IFFT frequency band corresponding thereto is allocated to a subframe having a basic bandwidth of 40 MHz.
- RS indicates a reference signal (Reference (Signal) arranged together when a response signal is transmitted on PUCCH
- ACK indicates an SC-FDMA symbol in which a spread response signal is arranged. .
- the response signal is spread in two stages.
- Response signal spreading section 165 spreads so that one symbol of the response signal occupies the entire 1SC-FDMA symbol in the first stage of spreading. That is, since one SC-FDMA symbol is formed by 12 Time-continuous signals, a spreading code having a sequence length of 12 is used in the first stage spreading.
- the response signal spreading section 165 converts the response signal having a length corresponding to one SC-FDMA symbol obtained in the first stage into a spreading code (for example, Walsh code) having a sequence length of 4. (1,1,1,1), (1, -1,1, -1), (1,1, -1, -1), or (1, -1, -1,1)) Spread.
- a spreading code for example, Walsh code
- Response signals having a length corresponding to the 4SC-FDMA symbols obtained in this way are arranged in four SC-FDMA symbols in one slot.
- FIG. 6 shows this arrangement state. Note that response signals from other terminals are spread with different spreading codes. Therefore, the receiving-side base station 200 can separate the response signals from the terminals by performing despreading in the CDMA technique on the received response signals.
- the frequency mapping unit 177 maps the PUCCH signal to the frequency position corresponding to the control channel assigned to the own device in the channel block arranged at one end.
- PUCCH1 of FIG. 6 the case where PUCCH1 of FIG.
- control unit 140 matches one end of the transmission band of the transmission RF unit 185 with one end of the extension band in which the control channel assigned to the own device is arranged.
- the control unit 140 is a weighting vector used in the precoding unit 178 Are switched between the front slot and the rear slot of the same subframe.
- the control unit 140 causes the frequency mapping unit 177 to map the PUCCH signal to the frequency position corresponding to the control channel assigned to the own device in the channel block arranged at one end.
- the control unit 140 matches the transmission band of the transmission RF unit 185 with the expansion band assigned to the own device. Specifically, the transmission RF unit 185 matches the center frequency of the transmission band with the center frequency of the extension band because the transmission bandwidth matches the bandwidth of the extension band.
- control unit 270 assigns each uplink subframe configuration pattern configured by 2 slots to each A control channel is arranged at both ends of a unit band, and a plurality of controls are provided at both ends of an extension band composed of a first pattern and a plurality of unit bands in which the control channels arranged at both ends of each unit band are interchanged between slots.
- Each of the channel blocks including the channel is arranged, and the frequency position of the constituent control channel is selected from the second pattern in each control channel block.
- Information on the selected configuration pattern is transmitted to the allocation target terminal to which the uplink subframe is allocated.
- a wide frequency region can be prepared between the control channels.
- a wide frequency region between the control channels is used as a channel (PUSCH) used for uplink data transmission, and by assigning this frequency region to a terminal capable of broadband communication, uplink high-speed data communication can be realized.
- PUSCH channel
- SC-FDMA uplink high-speed data communication by SC-FDMA can be realized.
- control section 140 indicates that the pattern information acquired by broadcast signal receiving section 125 indicates the second pattern, and the communicable bandwidth of the own device is the pattern information.
- the transmission bandwidth of the transmission RF unit 185 is adjusted to the extension band and the weighting vector used in the precoding unit 178 is set to the front slot and the rear slot. Change with.
- control unit 140 indicates that the pattern information acquired by the notification signal receiving unit 125 indicates the second pattern, and the basic bandwidth of the configuration pattern corresponding to the pattern information is more than the communicable bandwidth of the own device.
- the transmission band is large, the transmission band is matched with one end of the extension band, and the frequency position to which the control channel signal is mapped in the channel block arranged at the one end and the weighting vector are set to the front slot and the rear slot. And change.
- the terminal 100 capable of transmitting the control channel obtained together can be realized. Accordingly, since terminals can be allocated with good balance to frames in which subframes having different configuration patterns are mixed, a communication system with high frequency utilization efficiency can be realized.
- Embodiment 2 when a terminal is assigned to a subframe of the second pattern, the transmission antenna is switched between slots in the subframe.
- FIG. 7 is a block diagram showing a configuration of terminal 300 according to Embodiment 2 of the present invention.
- terminal 300 includes control section 310, response signal spreading section 320, SC-FDMA signal forming section 330, and antenna changeover switches 340 and 350.
- the terminal 300 has two antennas. Unlike the terminal 100 of the first embodiment, the terminal 300 includes one transmission RF unit 185, and thus includes one power amplifier (PA).
- PA power amplifier
- terminal 300 restricts the input signal to the reception system to the reception signal received via any one of antennas by antenna changeover switch 350. Therefore, unlike the terminal 100, the terminal 300 does not have the signal synthesis unit 115. Unlike terminal 100, terminal 300 does not have a precoding unit in SC-FDMA signal forming unit 330.
- the control unit 310 is configured to map a response signal in the transmission antenna, SC-FDMA signal, a transmission band, And the pattern of spreading applied to the response signal is controlled.
- control section 310 determines whether the configuration pattern of the uplink subframe to which the own apparatus is assigned is the first pattern or the second pattern.
- control section 310 outputs a mapping control signal for mapping the PUCCH signal (ie, response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to SC-FDMA signal forming section 330.
- mapping control signal for mapping the PUCCH signal (ie, response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to SC-FDMA signal forming section 330.
- the control unit 310 and the control unit 140 have the same function.
- control unit 310 switches the transmission antenna between the front slot and the rear slot of the same subframe. Specifically, control unit 310 switches the transmission antenna by switching the output destination antenna of antenna switching switch 340 using the transmission antenna switching signal. Thus, the response signal subjected to spatial hopping can be transmitted.
- the communicable bandwidth (bandwidth determined by the terminal capability (Capability)) of the own device is compared with the basic bandwidth of the second pattern.
- control unit 310 shortens the spreading code used in the response signal spreading unit 320 A spreading code for the format (Shortened format). At this time, control unit 310 matches the transmission band of transmission RF unit 185 with the extension band.
- the control unit 310 converts the spreading code used in the response signal spreading unit 320 into a shortened form (Shortened format). At this time, the control unit 310 matches the transmission band of the transmission RF unit 185 with one end of the extension band in which the control channel assigned to the own device is arranged. This transmission band adjustment is performed based on a center frequency instruction output from the control unit 310.
- Base station 200 basically assigns a second pattern subframe to terminal 300 that can spatially hop and transmit a response signal. Further, for example, a first pattern subframe is allocated to a terminal such as an LTE terminal that cannot transmit a response signal by spatial hopping.
- a subframe having a basic bandwidth of 40 MHz (that is, the second subframe in FIG. 8) is allocated to terminal 300.
- subframes with a basic bandwidth of 20 MHz (that is, the first and third subframes in FIG. 8) are allocated to LTE terminals.
- a separation distance between the allocation target terminal 300 and the base station 200 may be used as an allocation reference. That is, the shortened format (Shortened format) is a format in which the response signal is punctured by one SC-FDMA symbol as will be described later. is there. Accordingly, since the reception quality may be poor even when the separation distance from the base station 200 is large, for the terminal 300 having a large separation distance from the base station 200, as in the second pattern subframe. An uplink subframe with a small frequency hopping width of PUCCH may not be assigned.
- the terminal 300 does not need to dare to perform spatial hopping and can use the normal format PUCCH. I can do it.
- the separation distance between the terminal 300 and the base station 200 may be obtained from a position obtained from the GPS. Further, the reception power of the pilot signal transmitted from terminal 300 at base station 200 may be used as an index of the separation distance.
- control unit 310 is the same as the control unit 140 of the first embodiment (see FIG. 8).
- the control unit 310 controls (4) the transmission antenna instead of controlling the weighting vector used for (1) precoding, and (5) controls the pattern of spreading applied to the response signal.
- control section 310 determines whether the configuration pattern of the uplink subframe to which the own apparatus is assigned is the first pattern or the second pattern.
- the control unit 310 maps the response signal to one end of the IFFT frequency band in the SC-FDMA signal forming unit 175 in the previous slot of the same subframe, and maps the response signal to the other end in the rear slot. . (3) The control unit 310 matches the transmission band of the transmission RF unit 185 with the unit band assigned to itself. (4) The control unit 310 may switch between the front slot and the rear slot of the same subframe without switching the transmission antenna. (5) The control unit 310 sets the spreading code used by the response signal spreading unit 320 as a spreading code for a normal format.
- the control unit 310 determines that it is the second pattern, the control unit 310 compares the communicable bandwidth (bandwidth determined by the terminal capability (Capability)) with the basic bandwidth of the second pattern.
- the control unit 310 is in the frequency mapping unit 177 within the channel block arranged at one end.
- the PUCCH signal is mapped to the frequency position corresponding to the control channel assigned to the own device.
- the control unit 310 matches the transmission band of the transmission RF unit 185 with one end of the extension band in which the control channel allocated to the own device is arranged.
- the control unit 310 switches the transmission antenna between the front slot and the rear slot of the same subframe. That is, the control unit 310 performs spatial hopping processing between the front slot and the rear slot of the same subframe by switching the transmission antenna.
- the transmission antenna switching timing is the boundary between the front slot and the rear slot.
- the control unit 310 sets the spreading code used in the response signal spreading unit 320 as a spreading code for a shortened format.
- FIG. 9 is a diagram for explaining the response signal transmission operation by the terminal 300 when the communicable bandwidth of the own device is smaller than the basic bandwidth of the second pattern.
- terminal 300 having a transmittable bandwidth of 20 MHz and an IFFT frequency band corresponding thereto is allocated to a subframe having a basic bandwidth of 40 MHz.
- RS indicates a reference signal (Reference ⁇ Signal) arranged together when a response signal is transmitted on PUCCH
- ACK indicates an SC-FDMA symbol in which a spread response signal is arranged. .
- the response signal spread with the above-described normal format spreading code is arranged in four SC-FDMA symbols.
- the response signal spread with the spreading code for the shortened format (Shortened format) is arranged in three SC-FDMA symbols excluding the first SC-FDMA symbol in the slot.
- Response signal spreading section 320 spreads so that the response signal of one symbol occupies the entire one SC-FDMA symbol in the first stage of spreading. That is, since one SC-FDMA symbol is formed by 12 Time-continuous signals, a spreading code having a sequence length of 12 is used in the first stage spreading.
- response signal spreading section 320 spreads the response signal having a length corresponding to one SC-FDMA symbol obtained in the first stage with a spreading code having a sequence length of 3.
- a spreading code with a sequence length of 3 needs to be an orthogonal sequence because the response signal is code division multiplexed with other terminals. Therefore, in the present embodiment, (1,1,1), (1, e j2 ⁇ / 3 , e j4 ⁇ / 3 ), (1, e, which are DFT codes formed from 3 ⁇ 3 DFT matrix components. Either j4 ⁇ / 3 or e j2 ⁇ / 3 ) is used as a spreading code.
- the response signal having a length corresponding to the 3SC-FDMA symbol obtained in this way is arranged in three SC-FDMA symbols in one slot.
- FIG. 9 shows this arrangement state. That is, in the previous slot, response signals are arranged in four SC-FDMA symbols, while in the subsequent slot, the response signal of the first SC-FDMA symbol is thinned out and arranged in the other three SC-FDMA symbols.
- the control unit 310 is connected to the frequency mapping unit 177 at one end.
- the PUCCH signal is mapped to the frequency position corresponding to the control channel assigned to the own device in the arranged channel block.
- the control unit 310 matches the transmission band of the transmission RF unit 185 with the extension band assigned to the own device. Specifically, the transmission RF unit 185 matches the center frequency of the transmission band with the center frequency of the extension band because the transmission bandwidth matches the bandwidth of the extension band.
- the control unit 310 switches the transmission antenna between the front slot and the rear slot of the same subframe.
- control unit 310 performs spatial hopping processing between the front slot and the rear slot of the same subframe by switching the transmission antenna.
- the transmission antenna switching timing is the boundary between the front slot and the rear slot.
- the control unit 310 sets the spreading code used in the response signal spreading unit 320 as a spreading code for a shortened format.
- control section 310 indicates that the pattern information acquired by broadcast signal receiving section 125 indicates the second pattern, and the communicable bandwidth of the device itself is
- the transmission band of the transmission RF unit 185 is adjusted to the extension band, and the output destination antenna of the transmission RF unit 185 is set to the front slot and the rear slot. And change.
- the space diversity effect can be obtained. Therefore, by adopting a subframe configuration (that is, the second pattern) in which frequency hopping with a small hopping width is performed in a channel block arranged at one end of the extension band, the frequency fading resistance effect is reduced. Can be supplemented by the spatial diversity effect.
- control unit 310 indicates that the pattern information acquired by the notification signal receiving unit 125 indicates the second pattern, and the basic bandwidth of the configuration pattern corresponding to the pattern information is more than the communicable bandwidth of the own device.
- the transmission band is large, the transmission band is adjusted to one end of the extension band, the frequency position where the control channel signal is mapped in the channel block arranged at the one end, and the output destination antenna of the transmission RF unit 185 , Change between the front slot and the rear slot.
- the terminal 100 capable of transmitting the control channel obtained together can be realized. Therefore, since terminals can be allocated with good balance to frames in which subframes having different configuration patterns are mixed, a communication system with high frequency utilization efficiency can be realized.
- a shortened format is applied to the subsequent slot.
- a shortened format may be applied to the previous slot.
- transmission antenna switching is performed at the end SC-FDMA symbol of the previous slot, and the end SC-FDMA symbol is set as a non-transmission period of the response signal.
- the third embodiment is different from the first embodiment in the subframe configuration of the second pattern. Along with the difference in the subframe configuration, the terminal controls the spreading pattern applied to the response signal.
- FIG. 10 is a block diagram showing a configuration of terminal 400 according to Embodiment 3 of the present invention.
- terminal 400 includes control section 410 and response signal spreading section 420.
- control section 410 Based on the uplink allocation information received from PDCCH receiver 130 and the PUCCH arrangement information received from broadcast signal receiver 125, control section 410 maps the weighting vector used for precoding and the frequency position for mapping the response signal in the SC-FDMA signal.
- the transmission band and the spreading pattern applied to the response signal are controlled.
- PUCCH arrangement information includes uplink subframe configuration pattern information.
- the configuration pattern of the uplink subframe includes a first pattern in which control channels are arranged at both ends of each unit band, and a second pattern in which control channels are arranged at both ends of an extension band composed of a plurality of unit bands. There is.
- the unit bandwidth is the “basic bandwidth”
- the extension bandwidth is the basic bandwidth.
- control unit 410 outputs a mapping control signal for mapping the PUCCH signal (that is, the response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to the SC-FDMA signal forming unit 175.
- control unit 410 maps the response signal to one end of the IFFT frequency band in SC-FDMA signal forming unit 175 in the previous slot of the same subframe. In the rear slot, the response signal is mapped to the other end.
- the control unit 410 determines whether or not the configuration pattern of the uplink subframe to which the own device is assigned is the second pattern. When the second pattern is indicated, the control unit 410 determines the communicable bandwidth (terminal capability (Capability)) Is compared with the basic bandwidth of the second pattern.
- the control unit 410 changes the spreading code used in the response signal spreading unit 420 to the normal format.
- a spreading code for (Normal (format) is used.
- the control unit 410 does not move the transmission band of the transmission RF unit 185 while keeping the transmission band matched with the extension band.
- the control unit 410 converts the spreading code used in the response signal spreading unit 420 to a shortened format.
- the spreading code of The spreading code for the shortened format is the same as that described in the second embodiment.
- the control unit 410 further adjusts the transmission band of the transmission RF unit 185 so that the response signal is transmitted at one end portion of the extension band in the previous slot of the same subframe, and the response signal is the other end in the rear slot.
- the transmission band of the transmission RF unit 185 is adjusted so that the signal is transmitted by the unit. The adjustment of the transmission band is performed based on the center frequency instruction output from the control unit 410.
- the response signal spreading unit 420 spreads the modulated response signal using a spreading code in accordance with an instruction from the control unit 410 and outputs the spread response signal to the switching unit 170.
- FIG. 11 is a block diagram showing a configuration of base station 500 according to Embodiment 3 of the present invention.
- the base station 500 includes a control unit 510.
- the control unit 510 uses the first pattern in which the control channel is arranged at both ends of each unit band and the control channel arranged at both ends of each unit band is exchanged between the slots.
- the control channel is selected from the second pattern in which the control channels are arranged at both ends of the extension band composed of the unit band and the control channels arranged at both ends of the extension band are exchanged between the slots.
- Information indicating the selected configuration pattern is output to the notification signal generation unit 220.
- the configuration pattern of the uplink subframe is a first pattern in which control channels are arranged at both ends of each unit band, and control channels arranged at both ends of each unit band are switched between slots.
- a control channel is arranged at both ends of an expansion band composed of a pattern and a plurality of unit bands, and a control channel arranged at both ends of the expansion band is selected for each subframe from the second pattern in which the control channels are exchanged between slots. The That is, base station 500 schedules subframe configuration patterns.
- FIG. 12 shows the situation of uplink frames based on the scheduling of subframe configuration patterns by the base station.
- the base station 200 alternately selects the first pattern and the second pattern.
- the unit band has a bandwidth of 20 MHz.
- the extension band has a bandwidth corresponding to two unit bands, that is, a bandwidth of 40 MHz. That is, in the first pattern, 20 MHz is the basic bandwidth, and in the second pattern, 40 MHz is the basic bandwidth.
- Information indicating the selected configuration pattern is included in the broadcast information by the broadcast signal generation unit 220 and broadcast.
- base station 500 performs the following subframe allocation according to the terminal capability of the subframe allocation target terminal. That is, base station 500 assigns to each terminal an uplink subframe in which a configuration pattern having a basic bandwidth equal to or smaller than the transmittable bandwidth of each terminal is selected.
- subframes with a basic bandwidth of 20 MHz that is, the first and third subframes in FIG. 12. Assigned. Further, a subframe having a basic bandwidth of 40 MHz (that is, the second subframe in FIG. 12) is allocated to a terminal having a transmittable bandwidth of 40 MHz or more.
- an uplink subframe in which a configuration pattern having a base bandwidth wider than the transmittable bandwidth is selected is allocated to the terminal 400 that can use the shortened format (Shortened format) and can change the transmission bandwidth. Also good. That is, even the terminal 400 having only a 20 MHz transmittable bandwidth may be assigned to the second subframe in FIG. In FIG. 12, a shortened format PUCCH is represented in the second subframe.
- the separation distance between the terminal 400 to be allocated and the base station 500 may be used as an allocation reference. That is, since the shortened format is a format in which the response signal is punctured by one SC-FDMA symbol, there is a possibility that the reception SNR of the PUCCH at the receiving side (that is, the base station 500) is lowered. Accordingly, since the reception quality may be poor even when the separation distance from the base station 500 is large, a basic bandwidth wider than the transmittable bandwidth is provided for the terminal 400 having a large separation distance from the base station 500.
- the uplink subframe in which the configuration pattern having the above is selected may not be assigned.
- the separation distance between terminal 400 and base station 500 may be obtained from a position obtained from GPS. Further, the reception power of the pilot signal transmitted from terminal 400 at base station 500 may be used as an index of the separation distance.
- the base station 500 allocates an uplink subframe in which a configuration pattern having a base bandwidth as wide as possible is selected to a terminal having a broadband terminal transmission capability. By doing so, the allocation target terminal can transmit the uplink data signal at high speed on the PUSCH to which a central frequency region other than the PUCCHs at both ends (a continuous frequency band of about 30 MHz in FIG. 12) is allocated. .
- control section 410 (1) weighting vector used for precoding based on uplink allocation information addressed to itself and PUCCH arrangement information broadcast from base station 500, transmitted from base station 500 (2) The frequency position where the response signal is mapped in the SC-FDMA signal, (3) the transmission band, and (5) the spreading pattern applied to the response signal are controlled.
- control unit 410 first determines whether the configuration pattern of the uplink subframe to which the own device is assigned is the first pattern or the second pattern.
- control unit 410 compares the communicable bandwidth of the own device with the basic bandwidth of the second pattern.
- the control unit 410 sets the weighting vector used in the precoding unit 178 before the same subframe. Switch between slot and back slot. Here, the weighting vector switching timing is the boundary between the previous slot and the subsequent slot.
- the control unit 410 maps the response signal to the frequency position according to the configuration pattern of the uplink subframe.
- the control unit 410 adjusts the transmission band of the transmission RF unit 185 so that the response signal is transmitted at one end of the extension band in the previous slot of the subframe, and the response signal is transmitted at the other end in the subsequent slot. Thus, the transmission band of the transmission RF unit 185 is adjusted.
- the control unit 410 sets the spreading code used in the response signal spreading unit 420 as a spreading code for a shortened format.
- FIG. 13 is a diagram for explaining the response signal transmission operation by the terminal 400 when the communicable bandwidth of the own device is smaller than the basic bandwidth of the second pattern.
- terminal 400 having a transmittable bandwidth of 20 MHz and an IFFT frequency band corresponding thereto is allocated to a subframe having a basic bandwidth of 40 MHz.
- RS indicates a reference signal (Reference ⁇ Signal) arranged together when a response signal is transmitted on PUCCH
- ACK indicates an SC-FDMA symbol in which a spread response signal is arranged.
- the response signal spread by the above-described normal format spreading code is arranged in four SC-FDMA symbols.
- the response signal spread with the spreading code for the shortened format is arranged in three SC-FDMA symbols excluding the first SC-FDMA symbol in the slot.
- the control unit 410 matches one end of the transmission band with one end of the expansion band in the previous slot and expands the other end of the transmission band in the rear slot. Align with the other end of the band. By using two slots in this way, terminal 400 can cover the entire extension band having a bandwidth that exceeds the transmittable bandwidth of its own device.
- the transmission band of the transmission RF unit 185 is changed, since the frequency is not stable for a while after the change (that is, the frequency transition period), the transmission operation becomes unstable. Therefore, as described above, by setting the first SC-FDMA symbol in the subsequent slot as a non-transmission period in which no signal is transmitted, useless transmission operations can be prevented.
- the frequency mapping unit 177 maps the response signal after the DFT processing to the frequency position corresponding to the uplink subframe configuration pattern. However, since the IFFT frequency bandwidth in the IFFT unit 179 and the bandwidth of the extension band do not match, the frequency mapping unit 177 matches the IFFT after adjusting the frequency position and transmission band according to the configuration pattern of the uplink subframe. The response signal after DFT processing is mapped to the frequency position.
- FIG. 13 illustrates a case where PUCCH1 of FIG.
- the control unit 410 is a weighting vector used in the precoding unit 178 Are switched between the front slot and the rear slot of the same subframe.
- the weighting vector switching timing is the boundary between the previous slot and the subsequent slot.
- the control unit 410 maps the response signal to the frequency position according to the configuration pattern of the uplink subframe.
- the control unit 410 does not move the transmission band of the transmission RF unit 185 while keeping the transmission band matched with the extension band. That is, control section 410 matches the center frequency of the transmission band of transmission RF section 185 with the center frequency of the extension band assigned by base station 500.
- the control unit 410 sets the spreading code used in the response signal spreading unit 420 as a spreading code for a normal format.
- FIG. 14 is a diagram for explaining a response signal transmission operation by the terminal 400 when the communicable bandwidth and the basic bandwidth of the second pattern are equal.
- terminal 400 having a transmittable bandwidth of 40 MHz and an IFFT frequency band corresponding thereto is assigned to a subframe having a basic bandwidth of 40 MHz.
- RS indicates a reference signal (Reference ⁇ Signal) arranged together when a response signal is transmitted on PUCCH
- ACK indicates an SC-FDMA symbol in which a spread response signal is arranged. .
- a response signal spread with a spreading code for a normal format is arranged in four SC-FDMA symbols. Yes.
- frequency mapping unit 177 matches the response signal after the DFT processing at a frequency position according to the configuration pattern of the uplink subframe. Map. In FIG. 14, the case where PUCCH1 of FIG.
- the transmission RF unit 185 does not move while keeping the center frequency of the transmission band matched to the center frequency of the extension band.
- control unit 510 changes the configuration pattern of the uplink subframe configured by 2 slots to each unit.
- a control channel is arranged at both ends of the band, and a control channel is arranged at both ends of the extension band composed of a first pattern and a plurality of unit bands in which the control channels arranged at both ends of each unit band are interchanged between slots.
- the control channel arranged and arranged at both ends of the extension band is selected from the second pattern in which the control channels are exchanged between the slots.
- Information on the selected configuration pattern is transmitted to the allocation target terminal to which the uplink subframe is allocated.
- a wide frequency region can be prepared between the control channels.
- a wide frequency region between the control channels is used as a channel (PUSCH) used for uplink data transmission, and by assigning this frequency region to a terminal capable of broadband communication, uplink high-speed data communication can be realized.
- PUSCH channel
- SC-FDMA uplink high-speed data communication by SC-FDMA can be realized.
- control section 410 indicates that the pattern information acquired by broadcast signal receiving section 125 indicates the second pattern, and the pattern information is larger than the communicable bandwidth of the own device.
- the basic bandwidth of the configuration pattern corresponding to is larger, the weighting vector used in the precoding unit 178 is changed between the previous slot and the subsequent slot, and the transmission band of the transmission RF unit 185 is expanded in the previous slot. In the rear slot, the transmission band is moved to the other end of the extension band.
- FIG. 15 is a block diagram showing a configuration of terminal 600 according to Embodiment 4 of the present invention.
- terminal 600 has a control unit 610.
- control unit 610 Based on the uplink allocation information received from PDCCH receiver 130 and the PUCCH arrangement information received from broadcast signal receiver 125, control unit 610 is configured to transmit the response position in the transmission antenna, SC-FDMA signal, transmission band, And the pattern of spreading applied to the response signal is controlled.
- the control unit 610 outputs a mapping control signal for mapping the PUCCH signal (that is, the response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to the SC-FDMA signal forming unit 330.
- the control unit 610 maps the response signal to one end of the IFFT frequency band in the SC-FDMA signal forming unit 330 in the previous slot of the same subframe, In the rear slot, the response signal is mapped to the other end.
- the control unit 610 determines whether or not the configuration pattern of the uplink subframe to which the own device is assigned is the second pattern.
- control unit 610 outputs a mapping control signal for mapping the PUCCH signal (that is, the response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to the SC-FDMA signal forming unit 330.
- mapping control signal for mapping the PUCCH signal (that is, the response signal) to the frequency position corresponding to the configuration pattern of the uplink subframe to the SC-FDMA signal forming unit 330.
- the control unit 610 and the control unit 410 have the same function.
- control unit 610 switches the transmission antenna between the front slot and the rear slot of the same subframe. Specifically, control unit 610 switches the transmission antenna by switching the output destination antenna of antenna switching switch 340 using the transmission antenna switching signal. Thus, the response signal subjected to spatial hopping can be transmitted.
- control unit 610 compares its own communicable bandwidth (bandwidth determined by terminal capability (Capability)) with the basic bandwidth of the second pattern.
- the control unit 610 converts the spreading code used in the response signal spreading unit 320 into a shortened format.
- the spreading code for the shortened format is the same as that described in the second embodiment.
- the control unit 610 does not move the transmission band of the transmission RF unit 185 while keeping the transmission band matched with the extension band.
- control unit 610 uses the spreading code used in response signal spreading unit 320 for the shortened format.
- the spreading code of the control unit 610 further adjusts the transmission band of the transmission RF unit 185 so that the response signal is transmitted at one end of the extension band in the previous slot of the same subframe, and the response signal is the other end in the subsequent slot.
- the transmission band of the transmission RF unit 185 is adjusted so that the signal is transmitted by the unit. The adjustment of the transmission band is performed based on the center frequency instruction output from the control unit 610.
- control section 610 responds with (2) SC-FDMA signal based on uplink allocation information addressed to itself and transmitted from base station 500 and PUCCH arrangement information broadcast from base station 500.
- a frequency position for mapping a signal, (3) a transmission band, (4) a transmission antenna, and (5) a spreading pattern applied to a response signal are controlled.
- control unit 610 first determines whether the configuration pattern of the uplink subframe to which the own device is assigned is the first pattern or the second pattern.
- control unit 610 compares the communicable bandwidth of the own device with the basic bandwidth of the second pattern.
- the control unit 610 maps the response signal to the frequency position according to the configuration pattern of the uplink subframe Let (3) The control unit 610 adjusts the transmission band of the transmission RF unit 185 so that the response signal is transmitted at one end of the extension band in the previous slot of the subframe, and the response signal is transmitted at the other end in the subsequent slot. Thus, the transmission band of the transmission RF unit 185 is adjusted. (4) The control unit 610 switches the transmission antenna between the front slot and the rear slot of the same subframe. (5) The control unit 610 sets the spreading code used in the response signal spreading unit 320 as a spreading code for a shortened format.
- FIG. 16 is a diagram for explaining a response signal transmission operation by the terminal 600 when the communicable bandwidth of the own device is smaller than the basic bandwidth of the second pattern.
- terminal 600 having a transmittable bandwidth of 20 MHz and an IFFT frequency band corresponding thereto is assigned to a subframe having a basic bandwidth of 40 MHz.
- RS indicates a reference signal (Reference ⁇ Signal) arranged together when a response signal is transmitted on PUCCH
- ACK indicates an SC-FDMA symbol in which a spread response signal is arranged. .
- the response signal spread with the above-described normal format spreading code is arranged in four SC-FDMA symbols.
- the response signal spread with the spreading code for the shortened format is arranged in three SC-FDMA symbols excluding the first SC-FDMA symbol in the slot.
- the control unit 610 matches one end of the transmission band with one end of the expansion band in the previous slot and expands the other end of the transmission band in the rear slot. Align with the other end of the band. By using two slots in this way, terminal 600 can cover the entire extension band having a bandwidth that exceeds the transmittable bandwidth of its own device.
- the transmission band of the transmission RF unit 185 is changed, the frequency is not stable for a while after the change (that is, the frequency transition period), so that the transmission operation becomes unstable. Further, when the transmission antenna is switched, the transmission signal is not stable for a while. Therefore, as described above, by setting the first SC-FDMA symbol in the subsequent slot as a non-transmission period in which no signal is transmitted, useless transmission operations can be prevented.
- the frequency mapping unit 177 maps the response signal after the DFT processing to the frequency position corresponding to the uplink subframe configuration pattern. However, since the IFFT frequency bandwidth in the IFFT unit 179 and the bandwidth of the extension band do not match, the frequency mapping unit 177 matches the IFFT after adjusting the frequency position and transmission band according to the configuration pattern of the uplink subframe. The response signal after DFT processing is mapped to the frequency position. In FIG. 16, the case where PUCCH1 of FIG.
- the control unit 610 responds to the configuration pattern of the uplink subframe The response signal is mapped to the frequency position. (3) The control unit 610 does not move while keeping the transmission band of the transmission RF unit 185 matched to the extension band. That is, the control unit 610 matches the center frequency of the transmission band of the transmission RF unit 185 with the center frequency of the extension band assigned by the base station 500. (4) The control unit 610 switches the transmission antenna between the front slot and the rear slot of the same subframe. (5) The control unit 610 sets the spreading code used in the response signal spreading unit 320 as a spreading code for a shortened format.
- control section 610 indicates that the pattern information acquired by broadcast signal receiving section 125 indicates the second pattern, and is greater than the communicable bandwidth of the own device.
- the output destination antenna of the transmission RF unit 185 is changed between the front slot and the rear slot, and the transmission band of the transmission RF unit 185 is expanded in the front slot.
- the transmission band is moved to the other end of the extension band in the rear slot.
- the spatial diversity effect can be obtained in addition to the effect of improving the frequency fading resistance by frequency hopping, the communication quality of the uplink control channel can be further improved.
- Embodiment 1 As a result of comparison, when the basic bandwidth of the second pattern is smaller than or equal to the communicable bandwidth of the own device, and the communicable bandwidth of the own device is It is assumed that the terminal 100 transmits a response signal in a normal format (Normal format) whenever the bandwidth is smaller than the basic bandwidth of the second pattern. However, terminal 100 may transmit the response signal in the shortened format described in the second embodiment. By doing so, for example, in a system in which terminal 300 of Embodiment 2 and terminal 100 coexist, response signals transmitted from both terminals can be orthogonalized.
- a normal format Normal format
- the response signal for downlink data has been described as an example of the PUCCH signal.
- the PUCCH signal is not limited to this.
- CQI Channel Quality Indicator
- RI Rank Indicator
- SR Service Request
- the precoding unit 178 is arranged in front of the IFFT unit 179, but the arrangement of the precoding unit is not limited to this.
- one IFFT unit may be arranged for the signal output from the frequency mapping unit 177, and the precoding unit may be arranged immediately after the IFFT.
- a precoding unit may be arranged after the CP adding unit 180.
- a precoding unit may be arranged in front of the DFT unit 176 and a plurality of DFT units 176 and frequency mapping units 177 may be provided.
- Each functional block used in the description of the first to fourth embodiments is typically realized as an LSI that is an integrated circuit. These may be individually made into one chip, or may be made into one chip so as to include a part or all of them.
- the name used here is LSI, but it may also be called IC, system LSI, super LSI, or ultra LSI depending on the degree of integration.
- the method of circuit integration is not limited to LSI, and implementation with a dedicated circuit or a general-purpose processor is also possible.
- An FPGA Field Programmable Gate Array
- a reconfigurable processor that can reconfigure the connection and setting of circuit cells inside the LSI may be used.
- the base station and terminal of the present invention are useful for realizing a control channel arrangement method in a frame that can be used by terminals having various terminal capabilities while realizing wideband uplink data communication.
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Abstract
Description
[端末の構成]
図3は、本発明の実施の形態1に係る端末100の構成を示すブロック図である。図3において、端末100は、受信RF部105と、OFDM信号復調部110と、信号合成部115と、分離部120と、報知信号受信部125と、PDCCH受信部130と、PDSCH(Physical Downlink Shared Channel)受信部135と、制御部140と、受信エラー判定部145と、応答信号生成部150と、変調部155と、変調部160と、応答信号拡散部165と、切替部170と、SC-FDMA(Single-Carrier Frequency Division Multiple Access)信号形成部175と、送信RF部185とを有する。端末100は、アンテナを2つ有しているため、受信RF部105、OFDM信号復調部110、及び送信RF部185をそれぞれ2つずつ具備している。すなわち、端末100は、送信RF部185を2つ有しているので、2つのパワーアンプ(PA)を具備している。
図4は、本発明の実施の形態1に係る基地局200の構成を示すブロック図である。図4において、基地局200は、変調部205と、再送制御部210と、変調部215と、報知信号生成部220と、変調部225と、多重部230と、OFDM信号形成部235と、送信RF部240と、受信RF部245と、SC-FDMA信号復調部250と、分離部255と、データ受信部260と、応答信号受信部265と、制御部270とを有する。
(上りサブフレームの構成パタンの報知)
基地局200の制御部270において、上りサブフレームの構成パタンが、各単位バンドの両端部にコントロールチャネルが配置され且つ前記各単位バンドの両端部に配置されたコントロールチャネルがスロット間で入れ替わる第1パタン及び複数の単位バンドから構成される拡張バンドの両端部に複数のコントロールチャネルを含むチャネルブロックがそれぞれ配置され且つ各コントロールチャネルブロックにおいて構成コントロールチャネルの周波数位置がスロット間で入れ替わる第2パタンから、サブフレームごとに選択される。すなわち、基地局200は、サブフレームの構成パタンをスケジューリングする。
基地局200は、基本的には、空間ホッピングさせて応答信号を送信可能な端末100に対しては、第2パタンのサブフレームを割り当てる。また、例えば、LTE端末のように空間ホッピングさせて応答信号を送信できない端末に対しては、第1パタンのサブフレームを割り当てる。
端末100において、制御部140は、基地局200から送信された、自機宛の上り割り当て情報、及び、基地局200からブロードキャストされたPUCCH配置情報に基づいて、(1)プレコーディングに用いる重み付けベクトル、(2)SC-FDMA信号において応答信号をマッピングする周波数位置、及び、(3)送信帯域を制御する。
(1)制御部140は、要素が全て1の重み付けベクトルをプレコーディング部178に使用させても(つまり、実質的に、プレコーディング部178にプレコーディングさせなくても)、プレコーディング部178で用いられる重み付けベクトルを、同一サブフレームの前スロットと後スロットとで切り替えてもよい。
(2)制御部140は、同じサブフレームの前スロットでは、SC-FDMA信号形成部175におけるIFFT周波数帯域の一端部に応答信号をマッピングし、後スロットでは、他端部に応答信号をマッピングさせる。
(3)制御部140は、送信RF部185の送信帯域を、自機に割り当てられた単位バンドに合わせる。
制御部140は、第2パタンであると判断される場合には、自機の通信可能帯域幅(端末能力(Capability)により定まる帯域幅)と、第2パタンの基本帯域幅とを比較する。
(1)制御部140は、プレコーディング部178で用いられる重み付けベクトルを、同一サブフレームの前スロットと後スロットとで切り替える。ここでは、重み付けベクトルの切り替えタイミングは、前スロットと後スロットとの境界としている。
(2)制御部140は、周波数マッピング部177に、一端部に配置されるチャネルブロック内において自機に割り当てられたコントロールチャネルに対応する周波数位置にPUCCH信号をマッピングさせる。
(3)制御部140は、送信RF部185の送信帯域を、自機に割り当てられたコントロールチャネルが配置されている拡張バンドの一端部に合わせる。
(1)制御部140は、プレコーディング部178で用いられる重み付けベクトルを、同一サブフレームの前スロットと後スロットとで切り替える。
(2)制御部140は、周波数マッピング部177に、一端部に配置されるチャネルブロック内において自機に割り当てられたコントロールチャネルに対応する周波数位置にPUCCH信号をマッピングさせる。
(3)制御部140は、送信RF部185の送信帯域を、自機に割り当てられた拡張バンドに合わせる。具体的には、送信RF部185は、送信帯域幅と、拡張バンドの帯域幅とがマッチしているので、送信帯域の中心周波数を拡張バンドの中心周波数に合わせる。
実施の形態2では、端末が第2パタンのサブフレームに割り当てられた場合、そのサブフレームにおけるスロット間で送信アンテナを切り替える。
図7は、本発明の実施の形態2に係る端末300の構成を示すブロック図である。図7において、端末300は、制御部310と、応答信号拡散部320と、SC-FDMA信号形成部330と、アンテナ切り替えスイッチ340、350とを有する。端末300は、アンテナを2つ有している。端末300は、実施の形態1の端末100と異なり、送信RF部185を1つ有しているので、1つのパワーアンプ(PA)を具備している。また、端末300は、アンテナ切り替えスイッチ350により受信系への入力信号をいずれかのアンテナを介して受信した受信信号に制限している。従って、端末300は、端末100と異なり、信号合成部115を有していない。また、端末300は、端末100と異なり、SC-FDMA信号形成部330にプレコーディング部を有していない。
(基地局200による端末へのサブフレーム割り当て)
基地局200は、基本的には、空間ホッピングさせて応答信号を送信可能な端末300に対しては、第2パタンのサブフレームを割り当てる。また、例えば、LTE端末のように空間ホッピングさせて応答信号を送信できない端末に対しては、第1パタンのサブフレームを割り当てる。
自機宛の上り割り当て情報、及び、基地局200からブロードキャストされたPUCCH配置情報に基づく、(2)SC-FDMA信号において応答信号をマッピングする周波数位置、及び、(3)送信帯域の制御に関しては、制御部310は、実施の形態1の制御部140と同じである(図8参照)。
(2)制御部310は、同じサブフレームの前スロットでは、SC-FDMA信号形成部175におけるIFFT周波数帯域の一端部に応答信号をマッピングし、後スロットでは、他端部に応答信号をマッピングさせる。
(3)制御部310は、送信RF部185の送信帯域を、自機に割り当てられた単位バンドに合わせる。
(4)制御部310は、同一サブフレームの前スロットと後スロットとで、送信アンテナを切り替えなくても切り替えてもよい。
(5)制御部310は、応答信号拡散部320で用いられる拡散符号を、ノーマル形式(Normal format)用の拡散符号とする。
制御部310は、第2パタンであると判断される場合には、自機の通信可能帯域幅(端末能力(Capability)により定まる帯域幅)と、第2パタンの基本帯域幅とを比較する。
(2)制御部310は、周波数マッピング部177に、一端部に配置されるチャネルブロック内において自機に割り当てられたコントロールチャネルに対応する周波数位置にPUCCH信号をマッピングさせる。
(3)制御部310は、送信RF部185の送信帯域を、自機に割り当てられたコントロールチャネルが配置されている拡張バンドの一端部に合わせる。
(4)制御部310は、実施の形態1の制御部140と異なり、送信アンテナを、同一サブフレームの前スロットと後スロットとで切り替える。すなわち、制御部310は、送信アンテナを切り替えることにより、同一サブフレームの前スロットと後スロットとで空間ホッピング処理を行う。ここでは、図8に示すように、送信アンテナの切り替えタイミングは、前スロットと後スロットとの境界としている。
(5)制御部310は、応答信号拡散部320で用いられる拡散符号を、短縮形式(Shortened format)用の拡散符号とする。
(2)制御部310は、周波数マッピング部177に、一端部に配置されるチャネルブロック内において自機に割り当てられたコントロールチャネルに対応する周波数位置にPUCCH信号をマッピングさせる。
(3)制御部310は、送信RF部185の送信帯域を、自機に割り当てられた拡張バンドに合わせる。具体的には、送信RF部185は、送信帯域幅と、拡張バンドの帯域幅とがマッチしているので、送信帯域の中心周波数を拡張バンドの中心周波数に合わせる。
(4)制御部310は、実施の形態1の制御部140と異なり、送信アンテナを、同一サブフレームの前スロットと後スロットとで切り替える。すなわち、制御部310は、送信アンテナを切り替えることにより、同一サブフレームの前スロットと後スロットとで空間ホッピング処理を行う。ここでは、図8に示すように、送信アンテナの切り替えタイミングは、前スロットと後スロットとの境界としている。
(5)制御部310は、応答信号拡散部320で用いられる拡散符号を、短縮形式(Shortened format)用の拡散符号とする。
実施の形態3は、実施の形態1と比べて、第2パタンのサブフレーム構成が異なる。このサブフレーム構成の相違に伴い、端末は、応答信号に対して施す拡散のパタンを制御する。
図10は、本発明の実施の形態3に係る端末400の構成を示すブロック図である。図10において、端末400は、制御部410と、応答信号拡散部420とを有する。
(上りサブフレームの構成パタンの報知)
基地局500の制御部510において、上りサブフレームの構成パタンが、各単位バンドの両端部にコントロールチャネルが配置され且つ前記各単位バンドの両端部に配置されたコントロールチャネルがスロット間で入れ替わる第1パタン及び複数の単位バンドから構成される拡張バンドの両端部にコントロールチャネルが配置され且つ前記拡張バンドの両端部に配置されたコントロールチャネルがスロット間で入れ替わる第2パタンから、サブフレームごとに選択される。すなわち、基地局500は、サブフレームの構成パタンをスケジューリングする。
基地局500は、基本的には、サブフレームの割り当て対象端末に係る端末能力に応じて、次のようなサブフレーム割り当てを行う。すなわち、基地局500は、各端末に対して、各端末の送信可能帯域幅以下の基本帯域幅を持つ構成パタンが選択された上りサブフレームを割り当てる。
端末400において、制御部410は、基地局500から送信された、自機宛の上り割り当て情報、及び、基地局500からブロードキャストされたPUCCH配置情報に基づいて、(1)プレコーディングに用いる重み付けベクトル、(2)SC-FDMA信号において応答信号をマッピングする周波数位置、(3)送信帯域、及び、(5)応答信号に対して施す拡散のパタンを制御する。
自機が割り当てられた上りサブフレームの構成パタンが第2パタンであるときには、制御部410は、自機の通信可能帯域幅と、第2パタンの基本帯域幅とを比較する。
(1)制御部410は、プレコーディング部178で用いられる重み付けベクトルを、同一サブフレームの前スロットと後スロットとで切り替える。ここでは、重み付けベクトルの切り替えタイミングは、前スロットと後スロットとの境界としている。
(2)制御部410は、上りサブフレームの構成パタンに応じた周波数位置に応答信号をマッピングさせる。
(3)制御部410は、サブフレームの前スロットでは応答信号が拡張バンドの一端部で送信されるように送信RF部185の送信帯域を調整し、後スロットでは応答信号が他端部で送信されるように送信RF部185の送信帯域を調整する。
(5)制御部410は、応答信号拡散部420で用いられる拡散符号を、短縮形式(Shortened format)用の拡散符号とする。
(1)制御部410は、プレコーディング部178で用いられる重み付けベクトルを、同一サブフレームの前スロットと後スロットとで切り替える。ここでは、重み付けベクトルの切り替えタイミングは、前スロットと後スロットとの境界としている。
(2)制御部410は、上りサブフレームの構成パタンに応じた周波数位置に応答信号をマッピングさせる。
(3)制御部410は、送信RF部185の送信帯域を拡張バンドに合わせたまま移動させない。すなわち、制御部410は、送信RF部185の送信帯域の中心周波数と、基地局500により割り当てられた拡張バンドの中心周波数とを一致させる。
(5)制御部410は、応答信号拡散部420で用いられる拡散符号を、ノーマル形式(Normal format)用の拡散符号とする。
実施の形態4では、実施の形態2と同様に、送信アンテナを切り替えることにより、空間ホッピングを実現する。また、実施の形態4では、実施の形態3と同様のサブフレーム構成が用いられる。すなわち、本実施の形態に係る基地局は、実施の形態3の基地局500である。
上りサブフレームの構成パタンの報知、及び、基地局500による端末へのサブフレーム割り当てについては、実施の形態3と同様である。
端末600において、制御部610は、基地局500から送信された、自機宛の上り割り当て情報、及び、基地局500からブロードキャストされたPUCCH配置情報に基づいて、(2)SC-FDMA信号において応答信号をマッピングする周波数位置、(3)送信帯域、(4)送信アンテナ、及び、(5)応答信号に対して施す拡散のパタンを制御する。
自機が割り当てられた上りサブフレームの構成パタンが第2パタンであるときには、制御部610は、自機の通信可能帯域幅と、第2パタンの基本帯域幅とを比較する。
(2)制御部610は、上りサブフレームの構成パタンに応じた周波数位置に応答信号をマッピングさせる。
(3)制御部610は、サブフレームの前スロットでは応答信号が拡張バンドの一端部で送信されるように送信RF部185の送信帯域を調整し、後スロットでは応答信号が他端部で送信されるように送信RF部185の送信帯域を調整する。
(4)制御部610は、送信アンテナを、同一サブフレームの前スロットと後スロットとで切り替える。
(5)制御部610は、応答信号拡散部320で用いられる拡散符号を、短縮形式(Shortened format)用の拡散符号とする。
(2)制御部610は、上りサブフレームの構成パタンに応じた周波数位置に応答信号をマッピングさせる。
(3)制御部610は、送信RF部185の送信帯域を拡張バンドに合わせたまま移動させない。すなわち、制御部610は、送信RF部185の送信帯域の中心周波数と、基地局500により割り当てられた拡張バンドの中心周波数とを一致させる。
(4)制御部610は、送信アンテナを、同一サブフレームの前スロットと後スロットとで切り替える。
(5)制御部610は、応答信号拡散部320で用いられる拡散符号を、短縮形式(Shortened format)用の拡散符号とする。
(1)実施の形態1では、比較の結果、自機の通信可能帯域幅よりも第2パタンの基本帯域幅の方が小さいとき又は両者が等しいとき、及び、自機の通信可能帯域幅が第2パタンの基本帯域幅よりも小さいときのいずれでも、端末100が、ノーマル形式(Normal format)で応答信号を送信するものとした。しかしながら、端末100が、実施の形態2で説明した短縮形式(Shortened format)で応答信号を送信するようにしてもよい。こうすることで、例えば、実施の形態2の端末300と、端末100とが混在するシステムにおいて、両端末から送信される応答信号を互いに直交化させることができる。
Claims (4)
- 単一の通信に複数の単位バンドを割り当て可能な基地局であって、
2スロットで構成される上りサブフレームの構成パタンを、各単位バンドの両端部にコントロールチャネルが配置され且つ前記各単位バンドの両端部に配置されたコントロールチャネルがスロット間で入れ替わる第1パタン及び複数の単位バンドから構成される拡張バンドの両端部に複数のコントロールチャネルを含むチャネルブロックがそれぞれ配置され且つ各コントロールチャネルブロックにおいて構成コントロールチャネルの周波数位置がスロット間で入れ替わる第2パタンから選択する選択手段と、
前記上りサブフレームが割り当てられる割り当て対象端末に対して、前記選択された構成パタンに関する情報を送信する送信手段と、
を具備する基地局。 - 単一の通信に複数の単位バンドを割り当て可能な基地局によって割り当てられ且つ2スロットからなる上りサブフレームでSC-FDMAシンボルを送信する端末であって、
前記割り当てられた上りサブフレームの構成パタンが、各単位バンドの両端部にコントロールチャネルが配置され且つ前記各単位バンドの両端部に配置されたコントロールチャネルがスロット間で入れ替わる第1パタンであるか、又は、複数の単位バンドから構成される拡張バンドの両端部に複数のコントロールチャネルを含むチャネルブロックがそれぞれ配置され且つ各チャネルブロックにおいて構成コントロールチャネルの周波数位置がスロット間で入れ替わる第2パタンであるかを示すパタン情報を取得する取得手段と、
送信帯域を変更可能に構成され、前記SC-FDMAシンボルを送信する送信手段と、
前記SC-FDMAシンボルを形成する手段であって、コントロールチャネル信号を前記SC-FDMAシンボルにおける前記パタン情報に応じた周波数位置にマッピングするマッピング手段と、当該マッピング手段で得られた信号を重み付けベクトルでプレコーディングするプレコーディング手段と、を含む形成手段と、
前記取得したパタン情報が前記第2パタンを示し、且つ、自機の通信可能帯域幅よりも前記パタン情報に対応する構成パタンの基本帯域幅の方が大きいときに、前記送信帯域を前記拡張バンドの一端部に合わせて、当該一端部に配置されたチャネルブロック内において前記コントロールチャネル信号がマッピングされる周波数位置、及び、前記重み付けベクトルを、前スロットと後スロットとで変更する制御手段と、
を具備する端末。 - 単一の通信に複数の単位バンドを割り当て可能な基地局によって割り当てられ且つ2スロットからなる上りサブフレームでSC-FDMAシンボルを送信する端末であって、
前記割り当てられた上りサブフレームの構成パタンが、各単位バンドの両端部にコントロールチャネルが配置され且つ前記各単位バンドの両端部に配置されたコントロールチャネルがスロット間で入れ替わる第1パタンであるか、又は、複数の単位バンドから構成される拡張バンドの両端部に複数のコントロールチャネルを含むチャネルブロックがそれぞれ配置され且つ各チャネルブロックにおいて構成コントロールチャネルの周波数位置がスロット間で入れ替わる第2パタンであるかを示すパタン情報を取得する取得手段と、
送信帯域を変更可能に構成され、前記SC-FDMAシンボルを複数のアンテナを介して送信する送信手段と、
前記SC-FDMAシンボルを形成する手段であって、コントロールチャネル信号を前記SC-FDMAシンボルにおける前記パタン情報に応じた周波数位置にマッピングするマッピング手段を含む形成手段と、
前記取得したパタン情報が前記第2パタンを示し、且つ、自機の通信可能帯域幅よりも前記パタン情報に対応する構成パタンの基本帯域幅の方が大きいときに、前記送信帯域を前記拡張バンドの一端部に合わせて、当該一端部に配置されたチャネルブロック内において前記コントロールチャネル信号がマッピングされる周波数位置、及び、前記送信手段の出力先アンテナを、前スロットと後スロットとで変更する制御手段と、
を具備する端末。 - 前記制御手段は、前記コントロールチャネル信号を、前記後スロットを構成するSC-FDMAシンボル群のうち最初のSC-FDMAシンボルを除くSC-FDMAシンボルに配置させる、
請求項3に記載の端末。
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