WO2018173483A1 - 基地局、端末及び通信方法 - Google Patents
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Definitions
- the present disclosure relates to a base station, a terminal, and a communication method.
- 3GPP 3rd Generation Partnership Project
- NR New Radio
- LTE Long Term Evolution
- a terminal In NR, similarly to LTE, a terminal (UE: User Equipment) uses an uplink control channel (PUCCH: Physical Uplink Control Channel), and a response signal (ACK / NACK: Acknowledgement / It is under consideration to transmit NegativeSIAcknowledgment), downlink channel state information (CSI: Channel State Information), and uplink radio resource allocation request (SR: Scheduling Request) to the base station (eNG or gNB).
- PUCCH Physical Uplink Control Channel
- ACK / NACK Acknowledgement / It is under consideration to transmit NegativeSIAcknowledgment
- CSI Downlink channel state information
- SR Scheduling Request
- the PUCCH resources in LTE standardized by 3GPP include frequency domain and code domain resources (see Non-Patent Documents 1-3, for example).
- the PUCCH resource in LTE is defined by a resource block (RB: Resource) Block) (also called PRB: Physical RB) and a spreading code (CS: Cyclic Shift or orthogonal code) in the system band. Is done.
- the PUCCH resource in LTE is configured with 1 PRB in the frequency domain and 1 subframe (14 symbols) in the time domain.
- 3GPP TS 36.211 V13.4.0 “Evolved Universal Terrestrial Radio Access (E-UTRA); Physical channels and modulation (Release 13),“ December 2016.
- 3GPP TS 36.213 V13.4.0 Evolved Terrestrial Radio Access (E-UTRA); Physical layer procedures (Release 13), "December 2016.
- 3GPP TS 36.211 V13.4.0 “Evolved Universal Terrestrial Radio Access (E-UTRA); Physical channels channels and modulation (Release 13),“ December 2016. R1-1701553, "Final minutes from RAN1 # AH1_NR (Spokane ’s meeting),” ETSI, MCC, February 2017. R1-1704043, “WF on PUCCH resource allocation," LG Electronics, NTT DOCOMO, ETRI, CATT, February 2017.
- the PUCCH resource in LTE is composed of 1 PRB and 1 subframe, and information to be notified from the base station to the terminal for PUCCH resource allocation is the frequency resource (PRB number) and spreading code number (CS). Number or orthogonal code number).
- PRB number the frequency resource
- CS spreading code number
- NR requires a more flexible PUCCH design compared to LTE in order to accommodate various service requirements or transceiver performance.
- One aspect of the present disclosure contributes to provision of a base station, a terminal, and a communication method that can flexibly allocate PUCCH resources.
- a base station includes: a circuit that selects one combination from among a plurality of parameter combinations related to an uplink control channel (PUCCH) resource; and a resource setting indicating the plurality of combinations in a higher layer signaling And a transmitter for notifying the terminal of the selected combination by dynamic signaling.
- PUCCH uplink control channel
- a terminal receives higher layer signaling including a resource setting indicating a combination of a plurality of parameters related to an uplink control channel (PUCCH) resource, and indicates one combination among the plurality of combinations
- PUCCH uplink control channel
- a communication method selects one combination from a plurality of parameter combinations related to an uplink control channel (PUCCH) resource, and sets a resource setting indicating the plurality of combinations by higher layer signaling. And notifies the terminal of the selected combination by dynamic signaling.
- PUCCH uplink control channel
- a communication method receives higher layer signaling including a resource setting indicating a combination of a plurality of parameters related to an uplink control channel (PUCCH) resource, and selects one combination from the plurality of combinations. Dynamic signaling is received, and an uplink control signal is transmitted using the PUCCH resource represented by the plurality of parameters corresponding to the one combination indicated in the dynamic signaling among the plurality of combinations.
- PUCCH uplink control channel
- PUCCH resources can be flexibly allocated.
- FIG. 1 shows a configuration example of the NR slot.
- FIG. 2 shows an example of a PUCCH resource in LTE.
- FIG. 3 shows the slot types.
- FIG. 4 shows an example of an in-band PUCCH resource.
- FIG. 5 shows the configuration of the base station according to Embodiment 1.
- FIG. 6 shows the configuration of the terminal according to Embodiment 1.
- FIG. 7 shows the configuration of the base station according to Embodiment 1.
- FIG. 8 shows the configuration of the terminal according to Embodiment 1.
- FIG. 9 shows processing of the base station and terminal according to Embodiment 1.
- FIG. 10 shows an example of a correspondence relationship between the DCI bit and the Semi-static resource configuration according to the first embodiment.
- FIG. 11 illustrates an example of frequency domain resources according to the first modification of the first embodiment.
- FIG. 11 illustrates an example of frequency domain resources according to the first modification of the first embodiment.
- FIG. 12 shows an example of a parameter X notification method at the time of Localized transmission according to the first modification of the first embodiment.
- FIG. 13 shows an example of a parameter X notification method at the time of Distributed transmission according to the first modification of the first embodiment.
- FIG. 14 shows a setting example of the range of the parameter N offset according to the first modification of the first embodiment.
- FIG. 15 shows an example of an RB grid between Numerology with different subcarrier intervals.
- FIG. 16 shows a setting example of the parameters M PRB and D according to the second modification of the first embodiment.
- FIG. 17A shows a setting example of parameter D for ShortSPUCCH according to the third modification of the first embodiment.
- FIG. 17B shows a setting example of parameter D for LongLPUCCH according to the third modification of the first embodiment.
- FIG. 18 shows an example of Uplink control resource set according to the fifth modification of the first embodiment.
- FIG. 19 illustrates a problem according to the second embodiment.
- FIG. 20A shows an example of transmission in slot units.
- FIG. 20B shows an example of transmission in slot units.
- FIG. 21 shows an example of transmission in non-slot units.
- FIG. 22 shows an example of a PUCCH resource notification method according to the fourth embodiment.
- FIG. 23 shows an example of a PUCCH resource notification method according to a modification of the fourth embodiment.
- FIG. 24A shows a setting example of PUCCH resources according to Embodiment 5.
- FIG. 24B shows an example of a correspondence relationship between the DCI bit and the Semi-static resource configuration according to the fifth embodiment.
- FIG. 24B shows an example of a correspondence relationship between the DCI bit and the Semi-static resource configuration according to the fifth embodiment.
- FIG. 25A shows a setting example of a PUCCH resource in slot n according to the modification of the fifth embodiment.
- FIG. 25B shows a setting example of the PUCCH resource in slot n + 1 according to the modification of Embodiment 5.
- FIG. 25C shows a setting example of PUCCH resources in slot n + 2 according to the modification of Embodiment 5.
- FIG. 25D shows a setting example of a PUCCH resource in slot n + 3 according to the modification of Embodiment 5.
- FIG. 26 shows a setting example of PUCCH resources according to the sixth embodiment.
- a terminal transmits an uplink control signal such as an ACK / NACK signal (response signal), CSI, or SR to a base station using PUCCH.
- an uplink control signal such as an ACK / NACK signal (response signal), CSI, or SR to a base station using PUCCH.
- the terminal needs to specify the PUCCH resource used for transmission of the uplink control signal.
- the terminal notifies the terminal of a set of semi-static PUCCH resources using higher layer signals, and the terminal performs downlink control.
- DCI Downlink Control Information
- PUCCH resources in NR include time domain, frequency domain, and code domain resources.
- the time domain resource includes a slot and a symbol in the slot.
- FIG. 1 is a configuration example of a slot in NR (sometimes referred to as “NR slot”).
- the NR slot is composed of 7 symbols or 14 symbols.
- PUCCH resource allocation in LTE standardized by 3GPP will be described (for example, see Non-Patent Documents 1-3).
- PUCCH resources include frequency domain and code domain resources.
- the PUCCH resource is defined by a resource block (PRB) and a spreading code (CS) in the system band.
- PRB resource block
- CS spreading code
- PUCCH resources PRB and spreading code
- PUCCH Physical Downlink Control Channel
- an ACK / NACK signal for downlink data is transmitted using a PUCCH resource in a target subframe four subframes after the subframe in which the downlink data is transmitted.
- LTE TDD Time Division Duplex
- an ACK / NACK signal for downlink data is transmitted using PUCCH resources in a target subframe four or more subframes after the subframe in which the downlink data is transmitted.
- a time domain resource (uplink subframe) for transmitting PUCCH is fixed in association with a subframe in which downlink data is transmitted. For this reason, in LTE, it is not necessary to notify the time domain resource for transmitting the PUCCH to the terminal.
- the time domain resource (slot number) for transmitting the PUCCH to the terminal Etc. in order to flexibly change the time domain resource (slot position) for transmitting the PUCCH according to the service request condition or the processing performance of the terminal, the time domain resource (slot number) for transmitting the PUCCH to the terminal Etc.
- LTE PUCCH resources are composed of 1 PRB in the frequency domain and 1 subframe in the time domain. For this reason, in LTE, if a subframe in which PUCCH is transmitted is specified, it is not necessary to notify other information (for example, symbol information) about the time domain resource for transmitting PUCCH.
- the PUCCH transmission time can be flexibly changed according to service requirement conditions or terminal processing performance, such as 1 or 2 symbol PUCCH transmission or 3 or more (for example, 4 symbols or more) PUCCH transmission. Changes are being considered. Therefore, in NR, it is necessary to notify the terminal of information related to symbols for transmitting PUCCH in one slot regarding time domain resources for transmitting PUCCH. In addition, in NR, it is necessary to notify the terminal of the PUCCH transmission interval length (symbol length, etc.).
- the frequency domain resource for transmitting LTE PUCCH is composed of 1 PRB, and it is necessary to notify the location of the one PRB to the terminal.
- the frequency domain resource for transmitting LTE PUCCH is composed of 1 PRB, and it is necessary to notify the location of the one PRB to the terminal.
- parameters required for notification of PUCCH resource allocation increase for both time domain resources and frequency domain resources compared to LTE.
- the base station notifies a set of quasi-static PUCCH resources by upper layer signals, and actually uses DCI.
- a method for selecting a PUCCH resource to be used has been studied.
- the PUCCH resource for transmitting CSI or SR is explicitly notified semi-statically by an upper layer signal.
- the base station uses a plurality of PUCCH resources (for example, (4 PUCCH resources) to the terminal semi-statically and using the 2 bits of the downlink control signal (DCI) of the PDCCH to which the corresponding downlink data is allocated, the PUCCH that is actually used among the multiple PUCCH resources A method of selecting one resource is also employed.
- PUCCH resources slot position, symbol position, RB number, etc.
- PUCCH transmission section length or frequency domain resource mapping cannot be considered.
- NR does not need to consider all combinations of time domain resources and frequency domain resources in PUCCH resource allocation.
- the number of symbols in a slot that can be used as a PUCCH resource depends on the slot type (Downlink ⁇ ⁇ ⁇ ⁇ centric slot, Uplink centric slot, Downlink only slot, Uplink only slot, etc.) as shown in FIG.
- the maximum number of symbols in a slot that can be used as a PUCCH resource is 2 symbols in the case of Downlink centric slot, and 5 symbols in the case of Uplink centric slot.
- the maximum is 7 symbols.
- the number of symbols in the slot depends on the type of slot, it is not necessary to consider all combinations of parameters relating to slots and parameters relating to symbols as PUCCH resources.
- the number of symbols in a slot that can be used as a PUCCH resource may depend on a frequency resource (PRB) in a system band or a band that can be allocated to a terminal.
- PRB frequency resource
- two symbols can be used as PUCCH resources for PRBs with RB numbers # 0 to # 3, and RB numbers # N-4 to #N
- 5 symbols can be used as PUCCH resources.
- the PUCCH transmission interval length depends on the symbol position in the slot. For example, symbol number # 6 (that is, the last symbol in the slot) is not combined for PUCCH transmitted using two symbols. Also, for example, for PUCCH transmitted using 4 symbols, Downlink centric slot (UL symbol number 2) and Downlink only (slot (UL symbol number 0) shown in FIG. 3, or RB shown in FIG. There is no need to consider combinations with numbers # 0 to # 3 (number of UL symbols 2).
- the base station regarding allocation of PUCCH resources for transmitting an uplink control signal (for example, ACK / NACK signal), the base station indicates a combination of a plurality of parameters related to the PUCCH resources by an upper layer signal. Notify the terminal of the resource configuration (defined as “Semi-static resource configuration”), and select one parameter combination related to the PUCCH resource that is actually used by the DCI of the PDCCH to which the corresponding downlink data is assigned. .
- a parameter (Semi-static resource configuration) regarding the PUCCH resource that the base station notifies to the terminal by the higher layer signal as an example, information on the use of frequency domain resources (hereinafter referred to as X (0), X (1)) , ..., X (N x -1)), information on time domain resources (specifically, slots) (hereinafter, A (0), A (1), ..., A (N A -1)) ), Information on time domain resources (specifically, symbol positions in slots) (hereinafter referred to as B (0), B (1),..., B (N B -1)), and PUCCH transmission intervals Information (hereinafter referred to as C (0), C (1),..., C (N C ⁇ 1)).
- parameters related to PUCCH resources are not limited to these pieces of information.
- the granularity (unit) of the PUCCH resource will be described by taking the frequency domain as a PRB unit and the time domain as a symbol unit as an example. That is, it is assumed that PUCCH between different terminals is FDM by PRB and TDM by symbol. Note that the granularity (unit) of the PUCCH resource is not limited to these.
- the communication system includes a base station 100 and a terminal 200.
- FIG. 5 is a block diagram illustrating a configuration of the base station 100 according to each embodiment of the present disclosure.
- control section 101 selects one combination from among a plurality of parameter combinations related to uplink control channel (PUCCH) resources.
- PUCCH uplink control channel
- Transmitting section 114 notifies terminal 200 of resource configuration (Semi-static resource configuration) indicating a plurality of combinations by higher layer signaling and notifies terminal 200 of the selected combination by dynamic signaling (DCI).
- resource configuration Semi-static resource configuration
- DCI dynamic signaling
- FIG. 6 is a block diagram illustrating a configuration of the terminal 200 according to each embodiment of the present disclosure.
- receiving section 202 receives higher layer signaling including resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to uplink control channel (PUCCH) resources.
- Dynamic signaling (DCI) is received indicating one of the combinations.
- Transmitting section 219 transmits an uplink control signal using PUCCH resources represented by a plurality of parameters corresponding to one combination indicated by dynamic signaling among the plurality of combinations.
- FIG. 7 is a block diagram showing a configuration of base station 100 according to Embodiment 1 of the present disclosure.
- the base station 100 includes a control unit 101, a data generation unit 102, an encoding unit 103, a retransmission control unit 104, a modulation unit 105, an upper control signal generation unit 106, an encoding unit 107, Modulation section 108, downlink control signal generation section 109, encoding section 110, modulation section 111, signal allocation section 112, IFFT (Inverse Fast Fourier Transform) section 113, transmission section 114, antenna 115, A receiving unit 116, an FFT (Fast Fourier Transform) unit 117, an extracting unit 118, a CSI demodulating unit 119, a SRS (Sounding Reference Signal) measuring unit 120, a demodulating / decoding unit 121, a determining unit 122, Have
- the control unit 101 determines “Semi-static resource configuration” indicating a combination of a plurality of parameters related to the uplink resource notified to the terminal 200 by the higher layer signal.
- the uplink resource for example, transmits a PUCCH resource that transmits an ACK / NACK signal, a PUCCH resource that transmits a PeriodicPUCSI signal, a PUCCH resource that transmits an SR, a resource that transmits an Aperiodic CSI signal, a Periodic and an Aperiodic SRS Resources.
- the control unit 101 outputs the determined information to the upper control signal generation unit 106.
- the control unit 101 determines an uplink resource (that is, a combination of parameters notified by DCI) to be actually allocated to the terminal 200 from the Semi-static resource configuration notified to the terminal 200 by the higher layer signal. .
- the control unit 101 is notified by DCI from each of a PUCCH resource configuration that transmits an ACK / NACK signal, a resource resource configuration that transmits an Aperiodic resource CSI signal, and a resource resource configuration that transmits an Aperiodic resource SRS, included in the Semi-static resource configuration.
- the control unit 101 outputs the determined information to the downlink control signal generation unit 109.
- the control unit 101 outputs the determined information to the extraction unit 118 in order to correctly receive the signal from the terminal 200.
- control unit 101 determines radio resource allocation for downlink data for the terminal 200 and outputs downlink resource allocation information instructing resource allocation of downlink data to the downlink control signal generation unit 109 and the signal allocation unit 112.
- the data generation unit 102 generates downlink data for the terminal 200 and outputs the downlink data to the encoding unit 103.
- the encoding unit 103 performs error correction encoding on the downlink data input from the data generation unit 102, and outputs the encoded data signal to the retransmission control unit 104.
- the retransmission control unit 104 holds the encoded data signal input from the encoding unit 103 and outputs it to the modulation unit 105 during the initial transmission. In addition, when a NACK for the transmitted data signal is input from determination unit 122 described later, retransmission control unit 104 outputs corresponding retained data to modulation unit 105. On the other hand, when the ACK for the transmitted data signal is input from the determination unit 122, the retransmission control unit 104 deletes the corresponding retained data.
- Modulation section 105 modulates the data signal input from retransmission control section 104 and outputs the data modulation signal to signal allocation section 112.
- the upper control signal generation unit 106 generates a control information bit string using information (for example, semi-static resource configuration) input from the control unit 101, and outputs the generated control information bit string to the encoding unit 107.
- information for example, semi-static resource configuration
- the encoding unit 107 performs error correction encoding on the control information bit string input from the higher control signal generation unit 106 and outputs the encoded control signal to the modulation unit 108.
- Modulation section 108 modulates the control signal input from encoding section 107 and outputs the modulated control signal to signal allocation section 112.
- Downlink control signal generation section 109 generates a control information bit string (DCI) using information input from control section 101 (information on uplink resources actually used by terminal 200 and downlink resource allocation information).
- the generated control information bit string is output to the encoding unit 110. Since the control information may be transmitted for a plurality of terminals, the downlink control signal generation unit 109 may generate a bit string including the terminal ID of each terminal in the control information for each terminal.
- the downlink control signal generation unit 109 may generate a group common control information bit string addressed to a plurality of terminals by using information indicating the type of slot or the amount of resources available for uplink (number of symbols, etc.). Good.
- the encoding unit 110 performs error correction encoding on the control information bit string input from the downlink control signal generation unit 109, and outputs the encoded control signal to the modulation unit 111.
- the modulation unit 111 modulates the control signal input from the encoding unit 110 and outputs the modulated control signal to the signal allocation unit 112.
- the signal allocation unit 112 maps the data signal input from the modulation unit 105 to a radio resource based on the downlink resource allocation information input from the control unit 101. Further, the signal allocation unit 112 maps the control signal input from the modulation unit 108 or the modulation unit 111 to a radio resource. The signal allocation unit 112 outputs the downlink signal to which the signal is mapped to the IFFT unit 113.
- the IFFT unit 113 performs transmission waveform generation processing such as OFDM (Orthogonal Frequency Division Division) on the signal input from the signal allocation unit 112.
- IFFT section 113 adds a CP (not shown) in the case of OFDM transmission to which CP (Cyclic Prefix) is added.
- IFFT section 113 outputs the generated transmission waveform to transmission section 114.
- the transmission unit 114 performs RF (Radio-Frequency) processing such as D / A (Digital-to-Analog) conversion and up-conversion on the signal input from the IFFT unit 113, and wirelessly transmits the signal to the terminal 200 via the antenna 115. Send a signal.
- RF Radio-Frequency
- D / A Digital-to-Analog
- the receiving unit 116 performs RF processing such as down-conversion or A / D (Analog-to-Digital) conversion on the uplink signal waveform from the terminal 200 received via the antenna 115, and after receiving processing
- RF processing such as down-conversion or A / D (Analog-to-Digital) conversion
- a / D Analog-to-Digital
- the FFT unit 117 subjects the uplink signal waveform input from the receiving unit 116 to FFT processing for converting a time domain signal into a frequency domain signal.
- the FFT unit 117 outputs the frequency domain signal obtained by the FFT process to the extraction unit 118.
- the extraction unit 118 uses the CSI feedback signal, SRS, or ACK / NACK from the signal input from the FFT unit 117.
- the radio resource to which the signal is transmitted is extracted, and the component (CSI feedback signal, SRS signal, or ACK / NACK signal) of the extracted radio resource is extracted as the CSI demodulator 119, the SRS measurement unit 120, or the demodulator / decoder 121. To each output.
- the CSI demodulator 119 demodulates the CSI feedback signal input from the extractor 118 and outputs the demodulated information to the controller 101.
- the CSI feedback is used, for example, in the control unit 101 for controlling downlink allocation.
- the SRS measurement unit 120 measures the uplink channel quality using the SRS signal input from the extraction unit 118, and outputs the measured information to the control unit 101.
- the measured information is used, for example, by the control unit 101 for uplink allocation control (not shown).
- the demodulation / decoding unit 121 performs equalization, demodulation, and error correction decoding on the signal input from the extraction unit 118, and outputs the decoded bit sequence to the determination unit 122.
- determination section 122 determines whether the ACK / NACK signal transmitted from terminal 200 indicates ACK or NACK for the transmitted data signal. To do. The determination unit 122 outputs the determination result to the retransmission control unit 104.
- FIG. 8 is a block diagram showing a configuration of terminal 200 according to Embodiment 1 of the present disclosure.
- a terminal 200 includes an antenna 201, a reception unit 202, an FFT unit 203, an extraction unit 204, a downlink control signal demodulation unit 205, a higher control signal demodulation unit 206, and a downlink data signal demodulation unit 207.
- Error detection section 208 control section 209
- CSI generation section 210 encoding section 211, modulation section 212, ACK / NACK generation section 213, encoding section 214, modulation section 215, and SRS generation Unit 216
- signal allocation unit 217 IFFT unit 218, and transmission unit 219.
- the receiving unit 202 performs down-conversion or A / D (Analog-to-Digital) conversion on the signal waveform of the downlink signal (data signal and control signal) received from the base station 100 via the antenna 201.
- the received signal (baseband signal) obtained is output to the FFT unit 203.
- the FFT unit 203 performs FFT processing on the signal (time domain signal) input from the receiving unit 202 to convert the time domain signal into a frequency domain signal.
- the FFT unit 203 outputs the frequency domain signal obtained by the FFT processing to the extraction unit 204.
- the extraction unit 204 extracts a downlink control signal (DCI) from the signal input from the FFT unit 203 based on the control information input from the control unit 209 and outputs the downlink control signal (DCI) to the downlink control signal demodulation unit 205. Further, the extraction unit 204 extracts the upper control signal and the downlink data signal based on the control information input from the control unit 209, outputs the upper control signal to the upper control signal demodulation unit 206, and downloads the downlink data signal. The data is output to the data signal demodulator 207.
- DCI downlink control signal
- the downlink control signal demodulating unit 205 blind-decodes the downlink control signal input from the extracting unit 204 and determines that the downlink control signal is a control signal addressed to the own device, the downlink control signal demodulating unit 205 demodulates the control signal and outputs it to the control unit 209. .
- the higher control signal demodulation unit 206 demodulates the higher control signal input from the extraction unit 204 and outputs the demodulated higher control signal to the control unit 209.
- the downlink data signal demodulator 207 demodulates and decodes the downlink data signal input from the extractor 204 and outputs the decoded downlink data to the error detector 208.
- the error detection unit 208 performs error detection on the downlink data input from the downlink data signal demodulation unit 207, and outputs the error detection result to the ACK / NACK generation unit 213. Further, the error detection unit 208 outputs, as received data, downlink data determined as having no error as a result of error detection.
- the control unit 209 calculates radio resource allocation for the downlink data signal based on the downlink resource allocation information indicated in the control signal input from the downlink control signal demodulation unit 205, and extracts information indicating the calculated radio resource allocation To 204.
- control unit 209 includes a higher control signal (Semi-static resource configuration) input from the higher control signal demodulation unit 206 and a control signal input from the downlink control signal demodulation unit 205 (which is actually used by the terminal 200).
- the uplink resources used by terminal 200 PUCCH resources that transmit ACK / NACK signals, PUCCH resources that transmit Periodic CSI signals, PUCCH resources that transmit SR, A resource for transmitting an Aperiodic CSI signal, a resource for transmitting Periodic and Aperiodic SRS
- the control unit 209 outputs information on the configured uplink resource to the signal allocation unit 217.
- the CSI generation unit 210 generates a CSI feedback bit string using the measurement result (not shown) of the downlink channel quality measured in the terminal 200, and outputs the CSI feedback bit string to the encoding unit 211.
- the encoding unit 211 performs error correction encoding on the CSI feedback bit string input from the CSI generation unit 210, and outputs the encoded CSI signal to the modulation unit 212.
- Modulation section 212 modulates the CSI signal input from encoding section 211 and outputs the modulated CSI signal to signal allocation section 217.
- the ACK / NACK generation unit 213 generates an ACK / NACK signal (ACK or NACK) for the received downlink data based on the error detection result input from the error detection unit 208.
- the ACK / NACK generation unit 213 outputs the generated ACK / NACK signal (bit sequence) to the encoding unit 214.
- the encoding unit 214 performs error correction encoding on the bit sequence input from the ACK / NACK generation unit 213, and outputs the encoded bit sequence (ACK / NACK signal) to the modulation unit 215.
- Modulation section 215 modulates the ACK / NACK signal input from encoding section 214 and outputs the modulated ACK / NACK signal to signal allocation section 217.
- the SRS generation unit 216 generates an SRS sequence and outputs it to the signal allocation unit 217.
- the signal allocation unit 217 is a radio instructed by the control unit 209 for the CSI signal input from the modulation unit 212, the ACK / NACK signal input from the modulation unit 215, and the SRS sequence input from the SRS generation unit 216. Map to each resource.
- the signal allocation unit 217 outputs the uplink signal to which the signal is mapped to the IFFT unit 218.
- the IFFT unit 218 performs transmission waveform generation processing such as OFDM on the signal input from the signal allocation unit 217.
- IFFT section 218 adds CP (not shown) in the case of OFDM transmission to which CP (Cyclic Prefix) is added.
- CP Cyclic Prefix
- a DFT Discrete Fourier Transform
- the IFFT unit 218 outputs the generated transmission waveform to the transmission unit 219.
- the transmission unit 219 performs RF (Radio-Frequency) processing such as D / A (Digital-to-Analog) conversion and up-conversion on the signal input from the IFFT unit 218, and transmits the signal to the base station 100 via the antenna 201. Send a radio signal.
- RF Radio-Frequency
- D / A Digital-to-Analog
- FIG. 9 shows a processing flow of base station 100 and terminal 200 according to the present embodiment.
- the base station 100 notifies the terminal 200 of a synchronization signal (PSS (Primary Synchronization Signal) / SSS (Secondary Synchronization Signal)) or system information (MIB (Master Information Block) / SIB (System Information Block)) (ST101).
- PSS Primary Synchronization Signal
- SSS Secondary Synchronization Signal
- MIB Master Information Block
- SIB System Information Block
- base station 100 determines resource setting (Semi-static resource configuration) at the time of initial access for terminal 200 (ST103), and determines the determined Semi-static resource configuration, for example, cell specific information or group It transmits to the terminal as unique information (ST104).
- Terminal 200 acquires the Semi-static resource configuration transmitted from base station 100 (ST105).
- terminal 200 executes an initial access (random access) procedure (or RRC connection control) and the like with base station 100 (ST106).
- initial access random access
- RRC connection control or RRC connection control
- base station 100 determines resource configuration (Semi-static resource configuration) specific to terminal 200 (ST107).
- X Information on the use of frequency domain resources
- the information X regarding the use of the frequency domain resource there is a parameter indicating a PRB used for PUCCH transmission.
- time domain resources there is a parameter regarding the number of slots from PDCCH reception to which corresponding downlink data is allocated.
- the symbol number in the slot where the PUCCH transmission is started (for example, information indicating the number of the symbol at the tail (or head))
- the symbol number in the slot where the PUCCH transmission is started (for example, information indicating the number of the symbol at the tail (or head))
- the information C regarding the PUCCH transmission interval there is a parameter indicating the number of symbols used for PUCCH transmission.
- the frequency domain resource (PRB) and time domain resource (slot and symbol) of PUCCH are specified by the combination of parameters X, A, B, and C.
- the parameters X, A, B, and C are not limited to the above example.
- the base station 100 sets a plurality of parameters X, A, B, C and combinations of the parameters X, A, B, C constituting the PUCCH semi-static resource configuration. To do.
- base station 100 transmits the determined resource configuration (Semi-static resource configuration) specific to terminal 200 to terminal 200 by an upper layer signal (upper layer signaling) (ST108).
- the base station 100 uses PUCCH semi-static resource configuration indicating (M + 1) combinations (combinations corresponding to DCI bits described later) shown in FIG. ), X (1), ..., X (N x )), information on time domain resources (slots) (A (0), A (1), ..., A (N A )), time domain resources (in slot) (B (0), B (1), ..., B (N B )) and PUCCH transmission section information (C (0), C (1), ..., C (N C ))
- the terminal 200 is notified by an upper layer signal.
- the base station 100 notifies the terminal 200 of the correspondence between the semi-static resource configuration and the DCI bit (see, for example, FIG. 10) by an upper layer signal.
- Terminal 200 acquires resource settings included in the higher layer signal (ST109). In this way, terminal 200 obtains PUCCH Semi-static resource configuration by an upper layer signal from base station 100, whereby a plurality (M + 1) of MUCs that can be set as PUCCH frequency domain resources and time domain resources. Identify combinations.
- base station 100 determines information on uplink resources or downlink resources actually allocated to terminal 200 (uplink resource information notified by DCI) (ST110). At this time, the base station 100 selects a combination of parameters actually used for the terminal 200 from the Semi-static resource configuration (the combination of parameters related to uplink resources) notified to the terminal 200 by the higher layer signal in ST108. Select one.
- the base station 100 transmits the determined uplink resource information (one selected combination), downlink resource allocation information of downlink data, and the downlink data to the terminal 200 (ST111). That is, the base station 100 supports one combination corresponding to the resource actually used for the terminal 200 among the (M + 1) combinations of parameters X, A, B, and C shown in FIG. This is notified by DCI bits (dynamic signaling) of PDCCH to which downlink data to be assigned is allocated.
- DCI bits dynamic signaling
- Terminal 200 acquires uplink resource information (a combination of parameters selected by base station 100) (ST112).
- terminal 200 performs CRC (Cyclic Redundancy Check) on the downlink data, and if there is no error in the CRC calculation result, ACK is used, and if there is an error in the CRC calculation result, NACK is used as the ACK / NACK signal.
- Feedback is made to the base station 100 (ST113).
- the terminal 200 selects one combination (X, X) notified by the DCI bit from the association between the PUCCH Semi-static resource configuration notified by the higher layer signal and the DCI bit (see FIG. 10).
- A, B, C) is used to specify the PUCCH resource used for feedback of the ACK / NACK signal.
- the terminal 200 can also use the other uplink signals (CSI, SRS, SR) from the correspondence between the semi-static resource configuration and the DCI bit (see FIG. 10), as in the case of the ACK / NACK signal. What is necessary is just to transmit by the resource specified by one combination (X, A, B, C) notified by the DCI bit. At this time, the correspondence between the semi-static resource configuration of each signal (ACK / NACK signal, CSI, SRS, and SR) and the DCI bit may be different.
- base station 100 when base station 100 notifies terminal 200 of PUCCH resource allocation information, Semi-static indicating a combination of a plurality of parameters (X, A, B, C) related to PUCCH resources. Resource configuration is notified by higher layer signaling, and one combination used for actual allocation to terminal 200 is notified by DCI. That is, notification of PUCCH allocation is performed using both higher layer signaling and DCI.
- terminal 200 transmits an uplink control signal (ACK / ACK) with PUCCH resources represented by a plurality of parameters corresponding to one combination notified by DCI from the Semi-static resource configuration notified by higher layer signaling.
- NACK signal, CSI, SRS, SR is transmitted.
- the base station 100 may notify one combination (bit information) by DCI when assigning PUCCH, and actually uses the PUCCH resources (information X, A, B regarding frequency domain resources and time domain resources). , C) need not be notified each time PUCCH is allocated, so that an increase in DCI size can be suppressed.
- the base station 100 notifies a PUCCH resource configured by a plurality of combinations of frequency domain resources and time domain resources as a semi-static resource configuration by an upper layer, and from among a plurality of combinations of PUCCH resources by DCI. Since the combination actually used by terminal 200 can be dynamically changed, PUCCH resources can be flexibly allocated.
- a method using a bitmap can be considered.
- the bitmap-based method can realize flexible resource allocation, the overhead for notifying the information X on the use of the frequency domain resource by the upper layer signal increases. For example, when the number of PRBs corresponding to the bandwidth is N RB , N RB bits are required in the bitmap in order to notify information X on the use of frequency domain resources.
- NR is studying support for Localized transmission and Distributed transmission for PUCCH resource mapping.
- the information X regarding the use of the frequency domain resource includes the start position (offset value) (N offset ) from the end of the band (system band or band that can be allocated to the terminal 200), the number of consecutive PRBs (M PRB ), It can be expressed using four parameters: the number of clusters (N cluster ) and the distance (D) between clusters.
- FIG. 11 shows an example in which information (X (0), X (1),..., X (N x )) regarding the use of frequency domain resources is configured using the above four parameters.
- information (X (0), X (1),..., X (N x )) regarding the resource usage in the frequency domain is obtained from the start position (N offset ), If configured using four parameters, the number of consecutive PRBs (M PRB ), the number of clusters (N cluster ), and the distance between clusters (D), it is possible to notify the mapping method of both Localized transmission and Distributed transmission, In addition, it is possible to reduce the number of bits necessary for the notification of the information X regarding the frequency domain resource usage.
- the first modification by restricting the range of values that can be taken for each parameter constituting the information X relating to the frequency domain resource usage, notification of the information X relating to the usage of the frequency domain resource can be performed. It is possible to further reduce the number of necessary bits and the number of candidates for information (X (0), X (1),..., X (N x )) related to the use of frequency domain resources.
- the start position (N offset ) from the band edge may be based on the edge of the band supported by terminal 200.
- the range of the value of the start position (N offset ) from the band edge may be the bandwidth range supported by the terminal 200.
- NR supports Short PUCCH that transmits PUCCH using one or two symbols and Long PUCCH that transmits PUCCH using three or more symbols.
- Long PUCCH it has been studied to obtain a frequency diversity effect by applying frequency hopping within a slot. Therefore, when it is assumed that frequency hopping is applied symmetrically with respect to the system band or the center frequency within the band supported by the terminal 200, the range of the value of the start position (N offset ) from the band edge is the system band or A range that is half of the bandwidth supported by terminal 200 is sufficient.
- ⁇ Number of consecutive PRBs (M PRB )> The purpose of applying Long PUCCH using three or more symbols is to expand coverage. Therefore, from the viewpoint of using resources used for PUCCH transmission, it is more important to increase time domain resources than to increase frequency domain resources for Long PUCCH. In Long PUCCH, it is considered that the minimum unit of PUCCH resources in the frequency domain is 1 PRB.
- NR it is considered to specify a plurality of PUCCH formats in accordance with the number of bits transmitted on PUCCH.
- terminal 200 can specify the number of consecutive PRBs (M PRB ) according to the set PUCCH format.
- N cluster ⁇ Number of clusters (N cluster )>
- N cluster the minimum unit of PUCCH resources in the frequency domain.
- N cluster by limiting the range of values of the number of clusters (N cluster), it is possible to reduce the number of bits required to notify the number of clusters (N cluster).
- NR is studying Mixed numerology as a method for accommodating services with different requirements, in which signal waveforms with different subcarrier intervals are mixed in the same band.
- PRB is composed of 12 subcarriers regardless of the subcarrier interval.
- FDM Frequency Division Multiplexing
- the number of consecutive PRBs (M PRB ) and the distance (D) between clusters are set to powers of 2.
- FIG. 16 shows an example of an RB grid when a terminal 200 having a certain subcarrier interval (here, 15 kHz) and a terminal 200 having a subcarrier interval twice (30 kHz) are multiplexed. .
- the number of PRBs in the band can be raised to a power of two.
- the number of consecutive PRBs (M PRB ) and the distance (D) between clusters in the reference subcarrier interval (reference subcarrier interval) are defined as (M PRB, 0 ) and the distance between clusters (D 0 ), respectively.
- the terminal 200 in other subcarrier spacing, PRB number of successive (M PRB) and PRB number of consecutive in the reference subcarrier spacing distance (D) between the clusters (M PRB) and the distance between clusters (D) You may specify from each.
- the number of consecutive PRBs in other subcarrier intervals (M PRB ) and the distance between clusters (D) are the same as the number of PRBs in the reference subcarrier interval (M PRB, 0 ) and the distance between clusters (D 0 ). May be set.
- N and D 0 / N the frequency bandwidth of the number of consecutive PRBs and the distance between clusters may be the same between different subcarrier intervals.
- NR supports ShortSPUCCH that transmits PUCCH using one or two symbols and Long PUCCH that transmits PUCCH using three or more symbols.
- Short PUCCH it is studied to obtain frequency diversity effect by Distributed transmission.
- Long PUCCH it has been studied to obtain a frequency diversity effect by applying frequency hopping within a slot.
- Long ⁇ ⁇ PUCCH it is also conceivable to apply Localized transmission without applying cluster transmission (that is, Distributed transmission).
- the base station 100 uses the Short PUCCH as a parameter (D) that configures information (X (0), X (1),..., X (N x )) related to frequency domain resource use. Different information is notified in the case of Long PUCCH.
- the base station 100 notifies the distance between the clusters by the parameter (D) for the Short- PUCCH.
- base station 100 notifies the frequency hopping distance within the slot (or between slots). That is, the parameter D indicating the distance between clusters in the case of Short PUCCH indicates the frequency hopping distance in the case of Long PUCCH.
- NR supports Short PUCCH that transmits PUCCH using one or two symbols and Long PUCCH that transmits PUCCH using three or more symbols.
- the range of information (B (0), B (1),..., B (N B )) regarding time domain resources (symbol positions) is different between Short PUCCH and Long PUCCH. Furthermore, the range of information (B (0), B (1),..., B (N B )) regarding time domain resources (symbol positions) may vary depending on the PUCCH transmission interval (number of symbols of PUCCH resources). Good.
- the range of values that parameter B (n) can take in the case of 1 symbol Short ⁇ 1PUCCH is 0 to 6. That is, in the case of 1 symbol Short PUCCH, PUCCH transmission is possible using any symbol in the slot.
- the range of values that can be taken for parameter B (n) is 1 to 6 (start position from the tail) or 0 to 5 (start position from the head). That is, it is possible to exclude the tail or head one symbol in the slot from the range of values that B (n) can take.
- the minimum number of symbols is also considered to be 4 symbols. Therefore, the range of values that B (n) can take is 3 to 6 (start position from the tail) or 0 to 3 (start position from the head). That is, it is possible to exclude the tail or leading three symbols in the slot from the range of values that B (n) can take.
- information B (n) related to time domain resources can be taken in association with information related to PUCCH transmission sections (symbols) (C (0), C (1),..., C (N C )).
- the value may be limited.
- the information (C (0), C (1),..., C (N C )) regarding the PUCCH transmission interval can be taken in association with the information B (n) regarding the time domain resource (symbol position).
- the value may be limited. That is, the range of the parameter B and the parameter C may be associated with each other.
- FIG. 18 shows an example in which two Uplink Control resource sets Y1, Y2 are set.
- PUCCH Semi-static resource configuration is associated with Uplink control resource set, and Semi-static resource configuration is changed for each Uplink control resource set.
- different Uplink Control Resource set Y1 and Y2 are set for Long PUCCH and Short PUCCH, respectively.
- the PUCCH Semi-static resource configuration is configured from the Y1 resource set
- the PUCCH Semi-static resource configuration is configured from the Y2 resource set.
- the terminal-specific PDCCH in addition to the terminal-specific PDCCH, it is considered to use a group common downlink control signal (Group common PDCCH) for a plurality of terminals.
- the resource amount (for example, the number of symbols) of Uplink Control resource set can also be notified by Group common PDCCH.
- the PUCCH Semi-static resource configuration is composed of Y1 resource set, and the resource amount Z2 of Uplink Control resource set of Group common PDCCH is When notified, the PUCCH Semi-static resource configuration may be configured from a Y2 resource set.
- the elements that make up the resource sets that make up Semi-static resource configuration are not limited to the notification of the resource amount of Uplink Control Resource set by the Long PUCCH / Short PUCCH and Group common PDCCH described above. ), Slot number, or uplink resource amount.
- control resource set is sometimes called “CORESET”.
- Embodiment 1 the case has been described in which the PUCCH semi-static resource configuration is notified by a higher layer signal specific to the terminal.
- the terminal-specific higher layer signal cannot be used for the notification of the PUCCH semi-static resource configuration. Therefore, in the PUCCH resource allocation at the initial access stage, the semi-static resource configuration may be notified by a cell-specific or group-specific higher layer signal such as SIB.
- the PUCCH resource allocation required at the initial access stage is an allocation to the PUCCH that transmits the ACK / NACK signal for Message4.
- the base station 100 performs resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to the PUCCH resource to the terminal 200 using a cell-specific or group-specific upper layer signal (RMSI) such as SIB (RMSI).
- resource configuration Semi-static resource configuration
- RMSI cell-specific or group-specific upper layer signal
- SIB SIB
- One combination of parameters related to the PUCCH resource to be actually used can be selected by several bits of the DCI of the PDCCH to which the corresponding Message 4 is assigned.
- a mechanism for preventing PUCCH resources from colliding between the terminals 200 is required.
- a mechanism for preventing collision of PUCCH resources between terminals 200 there is a method of associating PUCCH resources with RNTI, PDCCH resources (for example, CCE) or PDSCH resources.
- RMSI cell-specific or group-specific upper layer signal
- the PUCCH that transmits the ACK / NACK signal for Message 4 needs robust transmission, so the ACK / NACK signal for Message 4
- Long-PUCCH may always be used.
- the PUCCH transmission interval (whether Long PUCCH or Short-PUCCH is used) of the ACK / NACK signal for Message 4 may be determined based on the transmission method of Message 2 or Message 3. For example, if Message 2 or Message 3 is transmission in slot units, Long-PUCCH is used for the ACK / NACK signal for Message 4, and if Message 2 or Message 3 is transmission in non-slot units, ACK / Short-PUCCH may be used for the NACK signal.
- the allocation of PUCCH resources when transmitting ACK / NACK signals in downlink HARQ has been described.
- the above-described PUCCH resource allocation is not limited to the case of transmitting downlink HARQ ACK / NACK signals, but can also be applied to the case of transmitting Aperiodic CSI.
- a similar method can also be applied to resource allocation for Aperiodic SRS that terminal 200 transmits to base station 100 for uplink CSI measurement.
- the base station and terminal according to the present embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, and will be described with reference to FIGS.
- Embodiment 1 the PUCCH resource allocation in the case of transmitting a downlink HARQ ACK / NACK signal has been described. Moreover, in Embodiment 1, it mentioned that the same resource allocation method is applicable also when transmitting Aperiodic
- PUCCH is also used for periodically transmitting CSI (periodic CSI) or SR. Similarly, there is periodic transmission for SRS (periodic SRS).
- the uplink control signals transmitted periodically are not notified to the dynamic terminal 200 by PDCCH. For this reason, terminal 200 notifies Semi-static resource configuration (combination of a plurality of parameters) by an upper layer signal as in the method described in Embodiment 1, and a combination of parameters related to resources actually transmitted by DCI Cannot be specified.
- the base station 100 needs to notify the terminal 200 of one or more combinations of parameters related to the resources to be actually transmitted in advance.
- the resource notified (set) to Semi-static is no longer an uplink resource, and the terminal It is conceivable that 200 cannot be used for the uplink control signal.
- the resources of PRB # 0 and symbol # 5 are set to semi-static as uplink resources.
- terminal 200 periodically transmits an uplink control signal using the resource, but the resources of PRB # 0 and symbol # 5 are set to a gap (gap) at a certain timing, and Semi- The resource assigned to static is no longer available.
- the base station 100 can notify the terminal 200 of the type of slot or the amount of resources (number of symbols, etc.) that can be used for uplink by Group common PDCCH.
- terminal 200 receives and decodes Group common PDCCH to acquire information on resources that can be used for uplink, and transmits a periodic signal assigned to Semi-static It is determined whether or not resources can be used.
- terminal 200 can use a resource for transmitting a periodic signal assigned to Semi-static, terminal 200 transmits a periodic uplink control signal (CSI, SRS, SR) using the resource. To do.
- CSI periodic uplink control signal
- the following methods 1 and 2 may be performed.
- the terminal 200 drops (non-transmits) periodic signal transmission.
- the periodic signal has no significant influence on the characteristics even if a part of transmission is missing. Therefore, since terminal 200 does not transmit a periodic signal with a symbol that is not an uplink resource, interference with a signal transmitted by another terminal using the resource can be prevented.
- the terminal 200 specifies a resource for transmitting a periodic signal using information on resources available for uplink obtained from the Group common PDCCH. For example, when the number N UL of uplink symbols is notified by Group common PDCCH, the terminal 200 specifies the symbol position B (n) by B (n) mod N UL . This method eliminates the need to drop periodic signals.
- terminal 200 identifies one symbol from the tail of the slot as symbol position B (n) by B (n) mod N UL . Accordingly, even when the number of uplink symbols in the slot dynamically changes, terminal 200 can transmit an uplink control signal using the uplink resource after the change.
- PUCCH resources can be flexibly allocated to uplink control signals transmitted periodically such as CSI (periodic CSI) or SR.
- the base station and terminal according to the present embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, and will be described with reference to FIGS.
- the resource notified to Semi-static is changed by dynamically changing the type of slot or the number of uplink symbols in the slot. The case where the resource is lost and cannot be used for transmission of the signal has been described (for example, see FIG. 19).
- the type of slot or the number of uplink symbols in the slot is also dynamic for resources that transmit aperiodic signals (ACK / NACK signal, Aperiodic CSI, Aperiodic SRS, etc.) as described in the first embodiment.
- base station 100 and terminal 200 implement the following method.
- the base station 100 instructs the terminal 200 to receive and decode the Group common PDCCH using the terminal-specific PDCCH or the like.
- this instruction from base station 100 is not necessary.
- the terminal 200 receives and demodulates the Group common PDCCH, and acquires information on resources that can be used for uplink. And terminal 200 specifies the resource which transmits a periodic signal using the information regarding the resource which can be used for the uplink obtained from Group common PDCCH. For example, when the number N UL of uplink symbols is reported by the Group common PDCCH, the terminal 200 specifies the symbol position B (n) by B (n) mod N UL .
- the terminal 200 does not drop the aperiodic signal.
- the source that can be used for transmitting the signal can be identified and transmitted.
- the base station and terminal according to the present embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, and will be described with reference to FIGS.
- the base station uses a higher layer signal to set resource settings (Semi) indicating a combination of a plurality of parameters related to PUCCH resources.
- resource settings for example, ACK / NACK signals
- -static resource -configuration
- a method of selecting one combination of parameters related to the PUCCH resource to be actually used is described based on several DCI bits of PDCCH to which the corresponding downlink data is allocated.
- parameters related to PUCCH resources can include time domain resources (slots) and time domain resources (symbol positions).
- NR is transmission in slot units (also called slot-based transmission or PDSCH mapping type A) and non-slot transmission (non-slot-based transmission, mini-slot-based transmission or PDSCH mapping type B). Support).
- FIG. 20A and 20B show an example of transmission in slot units.
- PDSCH downlink data channels
- PDCCH downlink control channels
- the ACK / NACK signal corresponding to the PDSCH shown in FIG. 20A is transmitted using the PUCCH of slot n + k shown in FIG. 20B.
- k is an integer of 0 or more.
- FIG. 21 shows an example of transmission in non-slot units.
- PDSCHs mapped to symbols # 6 and # 7 in slot n are scheduled by PDCCH mapped to symbols # 4 and # 5 in slot n.
- ACK / NACK signals corresponding to PDSCH are transmitted using PUCCHs of symbols # 12 and # 13 in slot n.
- a set of resources capable of transmitting PDCCH is defined as a downlink control resource set (Downlink control resource set, DL CORESET).
- DL CORESET in slot-by-slot transmission, is always mapped to 2 or 3 symbols at the beginning of the slot.
- DL CORESET in transmission in non-slot units, can be mapped to any symbol in the slot.
- DL CORESET can be mapped to 2 or 3 symbols at the beginning of a slot even in non-slot unit transmission.
- the terminal must distinguish whether DL-CORESET is DL-CORESET for slot-unit transmission or DL-CORESET for non-slot-unit transmission when DL-CORESET is mapped to the first 2 or 3 symbols of the slot. Don't be. Therefore, when DL CORESET is mapped to 2 or 3 symbols at the beginning of a slot, it is used to distinguish whether the DL CORESET is DL CORESET for slot unit transmission or DL CORESET for non-slot unit transmission. It is assumed that notifications are used. On the other hand, when DL CORESET is mapped to other than 2 or 3 symbols at the head of the slot, the terminal can recognize that DL CORESET is DL CORESET for non-slot unit transmission.
- the method for notifying the time domain resource (slot) and the time domain resource (symbol position), which are parameters related to the PUCCH resource is different between transmission in slot units and transmission in non-slot units.
- parameters related to time domain resources are not included in the resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to PUCCH resources.
- the base station 100 notifies the terminal 200 of a resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to the PUCCH resource by an upper layer signal. Also, the base station 100 selects one combination of parameters related to the PUCCH resource that is actually used, based on several bits of the DCI of the PDCCH to which the corresponding downlink data is assigned.
- the resource setting indicating the combination of a plurality of parameters related to the PUCCH resource includes, for example, a time domain resource (symbol position).
- base station 100 notifies terminal 200 of parameters (settings) related to time domain resources (slots) independently of the above resource settings, using higher layer signals. Then, base station 100 selects one slot (slot position) to be actually used according to several bits of DCI of PDCCH to which the corresponding downlink data is assigned.
- time domain resources slots
- time domain resources symbol positions
- a resource configuration Semi-static resource configuration
- the size of DCI for transmission and the size of DCI for transmission in non-slot units may be the same.
- the base station 100 may select and notify a parameter related to the PUCCH resource using the DCI of (X + Y) bits as shown in FIG.
- the X bit is used to select a time domain resource (slot) to be notified to the terminal 200 independently of other parameters related to the PUCCH resource. Used, the Y bit is used to select one parameter combination for PUCCH resources. On the other hand, in non-slot unit transmission (PDSCH mapping type B), the X + Y bit is used to select one parameter combination related to the PUCCH resource.
- the base station 100 can more flexibly allocate the slot position by notifying the terminal 200 of the slot position independently of the parameters related to other PUCCH resources in the transmission in slot units.
- the base station 100 can assign symbol positions more flexibly by notifying PUCCH resources in symbol units, for example. Therefore, according to the present embodiment, flexible time domain resources (slots or symbol positions) suitable for slot-unit transmission and non-slot-unit transmission can be allocated for PUCCH resource allocation.
- terminal 200 can recognize that DL CORESET is DL CORESET for non-slot unit transmission. Further, since transmission in non-slot units is assumed to be used for URLLC (Ultra Reliable Low Latency Communication) applications that require high reliability, the DCI size should be as small as possible.
- URLLC Ultra Reliable Low Latency Communication
- DL CORESET when DL CORESET is mapped to other than 2 or 3 symbols in the slot, for DL CORESET for non-slot unit transmission, as shown in FIG. 100 may select and notify parameters related to PUCCH resources using Y-bit DCI.
- the base station and terminal according to the present embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, and will be described with reference to FIGS.
- the number of symbols in a slot that can be used as a PUCCH resource depends on the slot type (Downlink centric slot, Uplink centric slot, Downlink only slot, Uplink only slot, etc.) as shown in FIG. .
- the terminal can know the slot type (the number of downlink symbols or the number of uplink symbols) by any of the notifications shown below.
- the first is Semi-static configuration (also called Semi-static DL / UL configuration). Semi-static configuration is notified by an RRC signal.
- the second is SFI (Slot Format Indicator). The SFI is notified by a group common downlink control signal (Group common PDCCH).
- the third is UE-specific assignment. The UE-specific assignment is notified by the terminal-specific DCI.
- Information on the PUCCH transmission interval in the resource setting indicating a combination of a plurality of parameters related to the PUCCH resource in the first embodiment is also one of UE-specific assignments.
- base station 100 does not notify terminal 200 of specific numerical values for the PUCCH transmission interval and symbol position in resource configuration (Semi-static resource configuration) using higher layer signals, but does not notify terminal 200.
- a method for determining the PUCCH transmission interval and the symbol position from the semi-static configuration or SFI to Implicit will be described.
- the base station 100 notifies the terminal 200 of a resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to the PUCCH resource by the higher layer signal, and several bits of DCI of the PDCCH to which the corresponding downlink data is allocated. To select one parameter combination related to the PUCCH resource to be actually used.
- a resource configuration Semi-static resource configuration
- the base station 100 notifies a command such as “according to semi-static configuration” or “according to SFI” instead of a specific numerical value.
- terminal 200 has that either or both of the parameter related to the time domain resource (symbol) and the parameter related to the PUCCH transmission interval “according to Semi-static configuration” or “according to SFI”.
- PUCCH is transmitted using the uplink symbol obtained by the Semi-static configuration notified by the RRC signal or the uplink symbol notified by SFI.
- the resource configuration (Semi-static resource configuration) notified by the higher layer signal does not include a specific numerical value indicating the symbol position or the number of symbols in the slot, and terminal 200 uses PUCCH
- a numerical value indicating the symbol position or the number of symbols of the resource is acquired by Semi-static configuration or SFI which is information indicating the slot type.
- the commands related to the PUCCH transmission interval are not limited to commands indicating “Semi-static configuration” or “SFI”, but “all UL symbols in slots” or “all UL symbols in slots—X symbols”, etc. May be a command indicating.
- the X symbol may be a cell-specific semi-static value or a value notified by SFI or UE-specific assignment. X may be in the range of 1 to 6 symbols.
- FIG. 24A shows an example of setting a PUCCH resource in the fifth embodiment
- FIG. 24B shows an example of a correspondence relationship between the DCI bit and the semi-static resource configuration in the fifth embodiment.
- the command “all UL symbols in the slot” for determining Implicit is notified about the parameter B related to the time domain resource (symbol) and the parameter C related to the PUCCH transmission interval.
- the PUCCH resource setting is not limited to the example illustrated in FIG. 24B, and may include, for example, a combination in which specific numerical values are set for the parameter B related to the time domain resource (symbol) and the parameter C related to the PUCCH transmission interval. Good.
- the terminal 200 can determine Implicitly that the time domain resource (symbol) is the first UL symbol in the slot obtained from the Semi-static configuration or SFI. For example, in FIG. 24A, terminal 200 is notified that PUCCH resources are symbols # 8 to # 13 in slot n by Semi-static configuration or SFI. Therefore, terminal 200 determines symbol # 8, which is the first UL symbol in slot n, as an assigned time domain resource (symbol).
- the terminal 200 also determines the PUCCH transmission interval from the UL symbol in the slot obtained from the semi-static configuration or SFI. For example, in FIG. 24A, terminal 200 determines 6 symbols of symbols # 8 to # 13, which are PUCCH resources in slot n, as assigned PUCCH transmission intervals (number of symbols).
- the PUCCH time domain resource is determined by UE-specific assignment.
- the base station 100 notifies the terminal 200 of both the semi-static configuration or SFI and the UE-specific assignment, the priority of each notification cannot be controlled, and the UE-specific assignment is always given priority.
- the base station 100 notifies terminal 200 of both the semi-static configuration or SFI and the UE-specific assignment, a plurality of types indicating a slot type are indicated. It is possible to control the priority of notifications (Semi-static configuration / SFI and UE-specific assignment).
- the base station 100 uses a time domain resource (symbol) in a DCI that notifies a combination of parameters related to a PUCCH resource to be actually used among resource settings (Semi-static resource configuration) indicating a combination of a plurality of parameters related to a PUCCH resource.
- resource settings Semi-static resource configuration
- the priority of UE-specific assignment can be increased.
- the base station 100 uses a time domain resource (symbol) in a DCI that notifies a combination of parameters related to a PUCCH resource to be actually used among resource settings (Semi-static resource configuration) indicating a combination of a plurality of parameters related to a PUCCH resource.
- resource settings Semi-static resource configuration
- the priority of Semi-static configuration / SFI notification can be increased.
- the terminal 200 can use the Semi-static configuration or SFI
- the time domain resource (symbol) and the PUCCH transmission interval are uplinked by the Semi-static configuration as in the fifth embodiment.
- PUCCH is transmitted using the uplink symbol notified by the symbol or SFI.
- the terminal 200 is notified by UE-specific assignment (that is, a time domain resource (symbol) determined by a combination of parameters related to the PUCCH resource and a PUCCH transmission interval).
- the PUCCH is transmitted using the uplink symbol that has been set.
- the number of uplink symbols obtained by the semi-static configuration or the number of uplink symbols notified by the SFI may be less than four symbols.
- terminal 200 may drop or postpone PUCCH transmission.
- FIGS. 25A to 25D show setting examples of PUCCH resources for slot n to slot n + 3 in the modification of the fifth embodiment. That is, FIGS. 25A to 25D show a case where terminal 200 transmits PUCCH using 4 slots.
- the terminal 200 based on the UL symbol (symbol position and number of symbols) notified by the semi-static configuration or SFI for each slot, The PUCCH resource allocated to terminal 200 is determined. As a result, as shown in FIGS. 25A to 25D, even when the slot type (the number of UL symbols in the slot) is different among a plurality of slots that transmit PUCCH, terminal 200 can allocate the PUCCH resource allocated to each slot. Can be specified.
- terminal 200 can determine the PUCCH resource of each slot based on the semi-static configuration or SFI, and thus can reduce the resource allocation overhead. Further, even when the PUCCH is transmitted using a slot having a different number of UL symbols in the slot, the terminal 200 can use the UL symbol without waste, so that resource utilization efficiency can be improved.
- the base station and terminal according to the present embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, and will be described with reference to FIGS.
- the base station uses a higher layer signal to set resource settings (Semi) indicating a combination of a plurality of parameters related to PUCCH resources.
- resource settings for example, ACK / NACK signals
- -static resource -configuration
- a method of selecting one combination of parameters related to the PUCCH resource to be actually used is described based on several DCI bits of PDCCH to which the corresponding downlink data is allocated.
- parameters related to PUCCH resources can include time domain resources (slots) and time domain resources (symbol positions).
- overhead of DCI bits for PUCCH resource notification can be reduced by eliminating explicit resource notification for some parameters of the PUCCH resource.
- the number of DCI bits is the same (when it is a fixed value), it is not necessary to consider some parameters for the combination of parameters, so that it is possible to notify another parameter more flexibly.
- the base station 100 notifies the terminal 200 of a resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to the PUCCH resource by the higher layer signal, and several bits of DCI of the PDCCH to which the corresponding downlink data is allocated.
- a resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to the PUCCH resource by the higher layer signal, and several bits of DCI of the PDCCH to which the corresponding downlink data is allocated.
- a function of notifying Implicit about one or a plurality of parameters in a resource configuration (Semi-static resource configuration) indicating a combination of a plurality of parameters related to the PUCCH resource is provided.
- a parameter to which the function of notifying Implicit is added information on frequency resources or information on code resources (cyclic shift or time domain orthogonal code (OCC)) can be considered.
- OCC cyclic shift or time domain orthogonal code
- Implicit there is a method of adding an additional offset to the parameter notified by DCI.
- an additional offset for example, based on an identifier (C-RNTI: Cell-Radio Network Temporary Identifier) of the terminal 200 or a CCE (Control Channel Element) used for the terminal 200, C-RNTI mod mod X or CCE mod X or the like can be used. Further, PDSCH resources may be used instead of CCE.
- the value of X may be a fixed value or a value set by an RRC signal.
- FIG. 26 shows an example of PUCCH resource setting in the present embodiment.
- allocation of PUCCH resources # 0 to # 7 will be described.
- Explicit notification Explicit indication
- the base station 100 notifies, for example, 8 PUCCHs with 1 bit, and Implicit notification (for example, an additional PUCCH resource collision between terminals 200). Offset).
- the base station 100 groups eight PUCCH resources # 0 to # 7 (candidate values) into PUCCH resources # 0 to # 3 and PUCCH resources # 4 to # 7, and 1-bit DCI Is used to notify one of the plural (two) groups (n DCI ) to the terminal explicitly .
- Terminal 200 adds an additional offset (CCE mod 4) to n DCI notified by 1-bit DCI, and determines the PUCCH resource as Implicit. Thereby, the base station 100 can allocate the PUCCH resources for the PUCCH resources # 0 to # 7 while avoiding the collision of the PUCCH resources between the terminals 200.
- At least one parameter of the plurality of parameters related to the PUCCH resource includes DCI (Explicit notification) indicating any one of a plurality of groups obtained by grouping a plurality of candidate values of the parameter.
- the terminal 200 is notified by an offset (Implicit notification) set for each terminal 200.
- Each functional block used in the description of the above embodiment is partially or entirely realized as an LSI that is an integrated circuit, and each process described in the above embodiment may be partially or entirely performed. It may be controlled by one LSI or a combination of LSIs.
- the LSI may be composed of individual chips, or may be composed of one chip so as to include a part or all of the functional blocks.
- the LSI may include data input and output.
- An LSI may be referred to as an IC, a system LSI, a super LSI, or an ultra LSI depending on the degree of integration.
- the method of circuit integration is not limited to LSI, and may be realized by a dedicated circuit, a general-purpose processor, or a dedicated processor.
- 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 present disclosure may be implemented as digital processing or analog processing. Further, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology. Biotechnology can be applied.
- the base station of the present disclosure notifies a terminal of a circuit that selects one combination from among a plurality of parameter combinations related to an uplink control channel (PUCCH) resource, and a resource setting indicating the plurality of combinations by higher layer signaling And a transmitter for notifying the terminal of the selected combination by dynamic signaling.
- PUCCH uplink control channel
- the plurality of parameters include a parameter indicating a frequency domain resource, a parameter indicating a slot, a parameter indicating a symbol position in the slot, and a parameter indicating the number of symbols.
- the frequency domain resource is represented by an offset value indicating a start position from the end of the band, the number of consecutive resource blocks, the number of clusters, and the distance between the clusters.
- the offset value indicates a start position from the end of the band supported by the terminal in the system band, and the range of the offset value is supported by the terminal in the system band. This is the range of the bandwidth of the band.
- the range of the offset value is a range that is half of the band.
- the number of resource blocks is 1 when the number of symbols of the PUCCH resource is greater than or equal to a threshold value.
- the number of consecutive resource blocks is associated with the PUCCH format.
- the number of clusters is 1 when the number of symbols of the PUCCH resource is greater than or equal to a threshold value.
- the distance between the clusters is specified from the bandwidth of the band and the number of consecutive resource blocks.
- the number of consecutive resource blocks and the distance between the clusters are powers of 2.
- the number of consecutive resource blocks in the first subcarrier interval and the distance between the clusters are in the second subcarrier interval. It is specified from the number of consecutive resource blocks and the distance between the clusters.
- the parameter indicating the distance between the clusters when the number of symbols of the PUCCH resource is less than a threshold indicates the distance of frequency hopping when the number of symbols of the PUCCH resource is greater than or equal to the threshold .
- the parameter range indicating the symbol position in the slot differs between the case where the number of symbols of the PUCCH resource is less than a threshold and the case where the number of symbols of the PUCCH resource is greater than or equal to the threshold.
- a parameter range indicating the symbol position in the slot is associated with a parameter indicating the number of symbols of the PUCCH resource.
- different resource settings are associated with a plurality of uplink control resource sets.
- the plurality of parameters included in the resource configuration are configured based on one control resource set associated with the PUCCH format among the plurality of control resource sets.
- the resource amount of the control resource set is notified from the base station to the terminal by Group common PDCCH, and the different resource settings correspond to the resource amount notified by the Group common PDCCH, respectively. It is attached.
- the base station of the present disclosure one of a first transmission method in units of slots and a second transmission method in units of non-slots is set for the terminal, and the first transmission method is set.
- the plurality of parameters include at least a parameter indicating a symbol position
- the transmitter notifies the terminal of a parameter indicating a slot independently of the resource setting
- the second When a transmission method is set, the plurality of parameters include at least a parameter indicating the slot and a parameter indicating a symbol position in the slot.
- the resource setting does not include a numerical value indicating the symbol position or the number of symbols in the slot, and the numerical value indicating the symbol position or the number of symbols is determined by the information indicating the type of the slot. Will be notified.
- At least one parameter of the plurality of parameters is set for each of the terminals, the dynamic signaling indicating any one of a plurality of groups obtained by grouping a plurality of candidate values of the parameters. Is notified to the terminal.
- the terminal of the present disclosure receives higher layer signaling including a resource setting indicating a combination of a plurality of parameters related to an uplink control channel (PUCCH) resource, and receives dynamic signaling indicating one combination of the plurality of combinations And a transmitter that transmits an uplink control signal using the PUCCH resource represented by the plurality of parameters corresponding to the one combination indicated in the dynamic signaling among the plurality of combinations.
- PUCCH uplink control channel
- one combination is selected from a plurality of parameter combinations related to an uplink control channel (PUCCH) resource, and resource settings indicating the plurality of combinations are notified to a terminal by higher layer signaling.
- the selected one combination is notified to the terminal by dynamic signaling.
- PUCCH uplink control channel
- the communication method of the present disclosure receives higher layer signaling including a resource configuration indicating a combination of a plurality of parameters related to an uplink control channel (PUCCH) resource, and performs dynamic signaling indicating one combination among the plurality of combinations. And receiving an uplink control signal using the PUCCH resource represented by the plurality of parameters corresponding to the one combination indicated in the dynamic signaling among the plurality of combinations.
- PUCCH uplink control channel
- One embodiment of the present disclosure is useful for a mobile communication system.
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Abstract
Description
[通信システムの概要]
本開示の各実施の形態に係る通信システムは、基地局100及び端末200を備える。
図7は、本開示の実施の形態1に係る基地局100の構成を示すブロック図である。図7において、基地局100は、制御部101と、データ生成部102と、符号化部103と、再送制御部104と、変調部105と、上位制御信号生成部106と、符号化部107と、変調部108と、下り制御信号生成部109と、符号化部110と、変調部111と、信号割当部112と、IFFT(Inverse Fast Fourier Transform)部113と、送信部114と、アンテナ115と、受信部116と、FFT(Fast Fourier Transform)部117と、抽出部118と、CSI復調部119と、SRS(Sounding Reference Signal)測定部120と、復調・復号部121と、判定部122と、を有する。
図8は、本開示の実施の形態1に係る端末200の構成を示すブロック図である。図8において、端末200は、アンテナ201と、受信部202と、FFT部203と、抽出部204と、下り制御信号復調部205と、上位制御信号復調部206と、下りデータ信号復調部207と、誤り検出部208と、制御部209と、CSI生成部210と、符号化部211と、変調部212と、ACK/NACK生成部213と、符号化部214と、変調部215と、SRS生成部216と、信号割当部217と、IFFT部218と、送信部219と、を有する。
以上の構成を有する基地局100及び端末200における動作について詳細に説明する。
X:周波数領域リソースの使用に関する情報
A:時間領域リソース(例えばスロット)に関する情報
B:時間領域リソース(例えばスロット内のシンボル位置)に関する情報
C:PUCCH送信区間に関する情報
周波数領域リソースの使用に関する情報Xの通知方法について説明する。
NRでは、端末200がサポートする帯域幅とシステム帯域とが異なり、端末200がサポートする帯域幅がシステム帯域幅より狭い場合も想定される。
3シンボル以上のシンボルを用いるLong PUCCHを適用する目的はカバレッジの拡張である。そのため、PUCCH送信に用いるリソース使用の観点からは、Long PUCCHに対して、周波数領域リソースを増加させるよりも、時間領域リソースを増加させることが重要である。また、Long PUCCHでは、周波数領域におけるPUCCHリソースの最小単位を1PRBとすることが検討されている。
前述したように、Long PUCCHについて、PUCCH送信に用いるリソース使用の観点からは、周波数領域リソースを増加させるよりも、時間領域リソースを増加させることが重要である。また、周波数領域におけるPUCCHリソースの最小単位を1PRBとすることが検討されている。また、クラスタ数を増加させると送信電力対平均電力比が高くなる。
クラスタ間の距離Dは、帯域幅及び連続するPRB数(MPRB)と関連した値をとることがある。例えば、帯域内のPRB数がNPRBの場合、クラスタ間の距離Dは、D=NPRB/MPRBと表すことができる。すなわち、端末200は、クラスタ間の距離DをパラメータXとして通知しなくても、帯域幅(NPRB)と連続するPRB数(MPRB)から特定することが可能である。
周波数領域リソースの使用に関する情報Xを構成する連続するPRB数(MPRB)及びクラスタ間の距離(D)について説明する。
周波数領域リソースの使用に関する情報Xを構成するパラメータ(D)について説明する。
時間領域リソース(シンボル位置)に関する情報Bについて説明する。
以下では、PUCCHを送信可能なリソースの集合を上りリンク制御リソースセット(Uplink control resource set)と定義する。図18は、2つのUplink Control resource setY1,Y2が設定された例を示す。
本実施の形態では、PUCCHのSemi-static resource configurationを端末固有の上位レイヤ信号で通知する場合について説明した。しかし、初期アクセスの段階(例えば、図9のST106以前の段階)では、PUCCHのSemi-static resource configurationの通知に端末固有の上位レイヤ信号を用いることはできない。したがって、初期アクセスの段階のPUCCHリソース割り当てでは、Semi-static resource configurationは、SIB等のセル固有又はグループ固有の上位レイヤ信号によって通知されてもよい。
本実施の形態に係る基地局及び端末は、実施の形態1に係る基地局100及び端末200と基本構成が共通するので、図7及び図8を援用して説明する。
端末200は、周期的な信号の送信をドロップ(非送信)する。ここで、周期的な信号は、一部の送信が欠けても特性に大きな影響が無いことが考えられる。よって、端末200が上りリンクリソースではないシンボルで周期的な信号を送信しないことにより、当該リソースを用いて他の端末が送信する信号への干渉を防ぐことができる。
端末200は、Group common PDCCHから得られる上りリンクに使用可能なリソースに関する情報を用いて、周期的な信号を送信するリソースを特定する。例えば、Group common PDCCHにより上りリンクのシンボル数NULが通知されている場合、端末200は、シンボル位置B(n)を、B(n) mod NULにより特定する。この方法では、周期的な信号をドロップする必要がなくなる。
本実施の形態に係る基地局及び端末は、実施の形態1に係る基地局100及び端末200と基本構成が共通するので、図7及び図8を援用して説明する。
本実施の形態に係る基地局及び端末は、実施の形態1に係る基地局100及び端末200と基本構成が共通するので、図7及び図8を援用して説明する。
実施の形態4では、DL CORESETがスロット先頭の2又は3シンボルにマッピングされる場合に、スロット単位の伝送と非スロット単位の伝送とでDCIサイズを同一にするために、基地局100が、X+YビットのDCIを用いて、PUCCHリソースに関するパラメータを選択/通知する場合について説明した。
本実施の形態に係る基地局及び端末は、実施の形態1に係る基地局100及び端末200と基本構成が共通するので、図7及び図8を援用して説明する。
実施の形態5では、単一スロットでPUCCHが送信される場合(例えば、図24Aを参照)について説明した。しかし、NRでは、複数スロットを用いてPUCCHを送信することもできる。複数スロットを用いてPUCCHを送信する場合、PUCCHを送信する複数のスロット間でスロットの種類(スロット内のULシンボルの数)が異なる場合がある。
本実施の形態に係る基地局及び端末は、実施の形態1に係る基地局100及び端末200と基本構成が共通するので、図7及び図8を援用して説明する。
101,209 制御部
102 データ生成部
103,107,110,211,214 符号化部
104 再送制御部
105,108,111,212,215 変調部
106 上位制御信号生成部
109 下り制御信号生成部
112,217 信号割当部
113,218 IFFT部
114,219 送信部
115,201 アンテナ
116,202 受信部
117,203 FFT部
118,204 抽出部
119 CSI復調部
120 SRS測定部
121 復調・復号部
122 判定部
200 端末
205 下り制御信号復調部
206 上位制御信号復調部
207 下りデータ信号復調部
208 誤り検出部
210 CSI生成部
213 ACK/NACK生成部
216 SRS生成部
Claims (23)
- 上りリンク制御チャネル(PUCCH)リソースに関する複数のパラメータの組み合わせの中から1つの組み合わせを選択する回路と、
前記複数の組み合わせを示すリソース設定を上位レイヤのシグナリングによって端末へ通知し、前記選択された1つの組み合わせをダイナミックシグナリングによって前記端末へ通知する送信機と、
を具備する基地局。 - 前記複数のパラメータには、周波数領域リソースを示すパラメータ、スロットを示すパラメータ、前記スロット内のシンボル位置を示すパラメータ、及び、シンボル数を示すパラメータが含まれる、
請求項1に記載の基地局。 - 前記周波数領域リソースは、帯域の端からの開始位置を示すオフセット値、連続するリソースブロック数、クラスタ数、前記クラスタ間の距離によって表される、
請求項2に記載の基地局。 - 前記オフセット値は、システム帯域のうち、前記端末がサポートする前記帯域の端からの開始位置を示し、
前記オフセット値の範囲は、システム帯域のうち、前記端末がサポートする前記帯域の帯域幅の範囲である、
請求項3に記載の基地局。 - 前記オフセット値の範囲は、前記帯域の半分の範囲である、
請求項3に記載の基地局。 - 前記PUCCHリソースの前記シンボル数が閾値以上の場合、前記リソースブロック数は1である、
請求項3に記載の基地局。 - 前記連続するリソースブロック数は、前記PUCCHのフォーマットに対応付けられている、
請求項3に記載の基地局。 - 前記PUCCHリソースの前記シンボル数が閾値以上の場合、前記クラスタ数は1である、
請求項3に記載の基地局。 - 前記クラスタ間の距離は、前記帯域の帯域幅と前記連続するリソースブロック数とから特定される、
請求項3に記載の基地局。 - 前記連続するリソースブロック数及び前記クラスタ間の距離は2のべき乗である、
請求項3に記載の基地局。 - 複数の異なるサブキャリア間隔が同一帯域に設定される場合、
第1のサブキャリア間隔における前記連続するリソースブロック数及び前記クラスタ間の距離は、第2のサブキャリア間隔における前記連続するリソースブロック数及び前記クラスタ間の距離からそれぞれ特定される、
請求項3に記載の基地局。 - 前記PUCCHリソースの前記シンボル数が閾値未満の場合に前記クラスタ間の距離を示すパラメータは、前記PUCCHリソースの前記シンボル数が前記閾値以上の場合に周波数ホッピングの距離を示す、
請求項3に記載の基地局。 - 前記スロット内のシンボル位置を示すパラメータの範囲は、前記PUCCHリソースの前記シンボル数が閾値未満の場合と、前記PUCCHリソースの前記シンボル数が前記閾値以上の場合とで異なる、
請求項2に記載の基地局。 - 前記スロット内のシンボル位置を示すパラメータの範囲と、前記PUCCHリソースの前記シンボル数を示すパラメータとが対応付けられている、
請求項2に記載の基地局。 - 上りリンクの複数の制御リソースセットに対して、異なる前記リソース設定が対応付けられている、
請求項1に記載の基地局。 - 前記リソース設定に含まれる前記複数のパラメータは、前記複数の制御リソースセットのうち、前記PUCCHのフォーマットに対応付けられた1つの制御リソースセットに基づいて構成される、
請求項15に記載の基地局。 - 前記制御リソースセットのリソース量がGroup common PDCCHによって前記基地局から前記端末へ通知され、
前記Group common PDCCHによって通知される前記リソース量に対して前記異なるリソース設定がそれぞれ対応付けられている、
請求項15に記載の基地局。 - 前記端末に対して、スロット単位の第1の伝送方法、及び、非スロット単位の第2の伝送方法の何れか一方が設定され、
前記第1の伝送方法が設定される場合、前記複数のパラメータには、少なくとも、シンボル位置を示すパラメータが含まれ、前記送信機は、スロットを示すパラメータを、前記リソース設定とは独立して前記端末へ通知し、
前記第2の伝送方法が設定される場合、前記複数のパラメータには、少なくとも、前記スロットを示すパラメータ、及び、前記スロット内のシンボル位置を示すパラメータが含まれる、
請求項1に記載の基地局。 - 前記リソース設定には、スロット内のシンボル位置又はシンボル数を示す数値が含まれず、前記シンボル位置又は前記シンボル数を示す数値は、前記スロットの種類を示す情報によって前記端末に通知される、
請求項1に記載の基地局。 - 前記複数のパラメータの少なくとも1つのパラメータは、当該パラメータの複数の候補値をグループ化した複数のグループの何れか1つを示す前記ダイナミックシグナリングと、前記端末毎に設定されるオフセットとによって前記端末に通知される、
請求項1に記載の基地局。 - 上りリンク制御チャネル(PUCCH)リソースに関する複数のパラメータの組み合わせを示すリソース設定を含む上位レイヤのシグナリングを受信し、前記複数の組み合わせの中の1つの組み合わせを示すダイナミックシグナリングを受信する受信機と、
前記複数の組み合わせのうち、前記ダイナミックシグナリングに示される前記1つの組み合わせに対応する前記複数のパラメータによって表される前記PUCCHリソースで上り制御信号を送信する送信機と、
を具備する端末。 - 上りリンク制御チャネル(PUCCH)リソースに関する複数のパラメータの組み合わせの中から1つの組み合わせを選択し、
前記複数の組み合わせを示すリソース設定を上位レイヤのシグナリングによって端末へ通知し、前記選択された1つの組み合わせをダイナミックシグナリングによって前記端末へ通知する、
通信方法。 - 上りリンク制御チャネル(PUCCH)リソースに関する複数のパラメータの組み合わせを示すリソース設定を含む上位レイヤのシグナリングを受信し、前記複数の組み合わせの中の1つの組み合わせを示すダイナミックシグナリングを受信し、
前記複数の組み合わせのうち、前記ダイナミックシグナリングに示される前記1つの組み合わせに対応する前記複数のパラメータによって表される前記PUCCHリソースで上り制御信号を送信する、
通信方法。
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JP7206185B2 (ja) | 2023-01-17 |
US20190380125A1 (en) | 2019-12-12 |
KR20190128645A (ko) | 2019-11-18 |
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AU2018238318B2 (en) | 2022-03-17 |
US20230413273A1 (en) | 2023-12-21 |
EP3606229A4 (en) | 2020-03-18 |
ZA201905625B (en) | 2021-01-27 |
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JP7372393B2 (ja) | 2023-10-31 |
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RU2019128193A (ru) | 2021-04-23 |
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RU2021121732A (ru) | 2021-09-23 |
BR112019016812A2 (pt) | 2020-04-07 |
US11432268B2 (en) | 2022-08-30 |
KR102572373B1 (ko) | 2023-08-29 |
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