JP7313513B2 - Terminal, communication method and integrated circuit - Google Patents

Description

The present disclosure relates to terminals, communication methods and integrated circuits.

With the spread of services using mobile broadband in recent years, data traffic in mobile communications continues to increase exponentially, and expansion of data transmission capacity is an urgent task for the future. In the future, there are high expectations for the rapid development of IoT (Internet of Things), in which all kinds of "things" are connected via the Internet. In order to support the diversification of services by IoT, not only data transmission capacity but also various requirements such as low latency and communication area (coverage) are required to dramatically improve. Against this background, technological development and standardization of the 5th generation mobile communication system (5G), which significantly improves performance and functions compared to the 4th generation mobile communication systems (4G), is underway.

One of 4G radio access technologies (RAT: Radio Access Technology) is LTE (Long Term Evolution)-Advanced standardized by 3GPP (3rd Generation Partnership Project). 3GPP is promoting the development of a new radio access technology (NR: New RAT) that does not necessarily have backward compatibility with LTE-Advanced in the standardization of 5G.

LTE-Advanced extension expands the existing LTE operating bandwidths (1.4, 3, 5, 10, 15 and 20 MHz) and flexibly supports various bandwidths (e.g. 1.8, 2.0, 2.2, 4.4, 4.6, 6.0, 6.2, 7.0, 7.8, 8.0, 11, 14, 18 and 19 MHz) to maximize the use of frequency bands allocated to operators and increase system throughput. Improvements are being considered (see, for example, Non-Patent Document 1).

NR is expected to support an operational bandwidth of several hundred MHz. On the other hand, the power consumption of terminals increases in proportion to the radio frequency (RF) bandwidth. Therefore, in NR, when a terminal receives a downlink control signal with a bandwidth similar to the operational bandwidth of the network, as in LTE, the power consumption of the terminal increases. Therefore, NR allows terminals to receive downlink control signals in a narrow band compared to the operating bandwidth of the network, so that the RF bandwidth of the terminal can be flexibly changed as necessary (for example, expanding the RF bandwidth of the terminal when transmitting and receiving data signals) is being studied (see, for example, Non-Patent Documents 2 and 3).

One of the methods for expanding the band is carrier aggregation (CA: Carrier Aggregation) introduced in LTE-Advanced. CA is a method of expanding a band by combining multiple bands (component carriers) of the existing LTE operating bandwidth. Therefore, when applying CA to the above-mentioned system that can flexibly change the bandwidth, some frequency bandwidths (e.g., 1.8, 2.0, 2.2, 4.6, 6.2, 7.0, 14 and 19 MHz) cannot be used with the combination of existing LTE operating bandwidths. In addition, CA that combines narrow-bandwidth component carriers requires control signal transmission and scheduling for each component carrier, which increases control signal overhead and is not efficient. Also, terminals must have CA capability even if the operating bandwidth is narrow. For example, for 11 MHz, the terminal needs the ability to combine 3 component carriers of 5 MHz+3 MHz+3 MHz. Hence, terminal complexity is increased.

Therefore, as a method of extending the band without using CA capabilities and mechanisms, a method of adding an extension band called a segment to the existing LTE band is being studied (see, for example, Non-Patent Document 4). With this method, existing LTE bands (also referred to as Backward Compatible Carrier (BCC)) and segments can be scheduled using one downlink control signal, so it is possible to reduce control signal overhead. In addition, in this method, even if the operating bandwidth is narrow, the terminal does not need to be equipped with CA capability, so it is possible to reduce the complexity of the terminal. Therefore, the method of adding segments is more efficient than the CA mechanism in the above-mentioned various bandwidth flexibly supporting system.

RP-151890, "Motivation for new work item proposal on LTE bandwidth flexibility enhancements," Huawei, China Unicom, HiSilicon, RAN#70, December 2015. R1-1613218, "Way Forward on UE bandwidth adaptation in NR," MediaTek, Acer, AT&T, CHTTL, Ericsson, III, InterDigital, ITRI, NTT Docomo, Qualcomm, Samsung, Verizon, RAN1#87, November 2016. RAN1#85 chairman's note R1-130786, "Way Forward on synchronized carrier and segment," Panasonic, KDDI, AT&T, Qualcomm, Motorola Mobility, New Postcom, Interdigital, RAN1#72,February 2013. 3GPP TS 36.213 V13.3.0, "Evolved Universal Terrestrial Radio Access (E-UTRA); Physical layer procedures (Release 13),"September 2016. 3GPP TS 36.211 V13.3.0, “Evolved Universal Terrestrial Radio Access (E-UTRA); Physical channels and modulation (Release 13),” September 2016.

In the above-mentioned wireless communication system that flexibly supports various bandwidths in LTE-Advanced and in the wireless communication system that allows flexible change of the RF bandwidth of the terminal in NR, when the method of adding segments is applied, it is necessary to study detailed mechanisms such as a method of determining parameters required for operation in a flexible bandwidth (for example, the bandwidth after adding a segment).

One aspect of the present disclosure contributes to providing a base station, a terminal, and a communication method capable of appropriately determining parameters required for operation with flexible bandwidths.

A base station according to an aspect of the present disclosure includes: a circuit that determines parameters for a second band composed of the first band and a segment that is an additional band to the first band; and a transceiver that communicates with the terminal in the second band using the parameters.

A terminal according to an aspect of the present disclosure includes: a circuit that determines parameters for a second band composed of the first band and a segment that is an additional band to the first band; and a transceiver that communicates with a base station in the second band using the parameters.

A communication method according to an aspect of the present disclosure determines parameters for a second band composed of the first band and a segment that is an additional band to the first band, and uses the parameters to communicate with the terminal in the second band.

A communication method according to an aspect of the present disclosure determines parameters for a second band composed of the first band and a segment that is an additional band to the first band, and uses the parameters to communicate with the base station in the second band.

It should be noted that these general or specific aspects may be realized by systems, methods, integrated circuits, computer programs, or recording media, and may be realized by any combination of systems, devices, methods, integrated circuits, computer programs, and recording media.

According to one aspect of the present disclosure, it is possible to appropriately determine parameters required for operation with flexible bandwidth.

Further advantages and advantages of one aspect of the present disclosure are apparent from the specification and drawings. Such advantages and/or advantages are provided by some of the embodiments and features described in the specification and drawings, respectively, but not necessarily all to obtain one or more of the same features.

FIG. 1 is a block diagram showing the configuration of a base station according to Embodiment 1; Block diagram showing the configuration of a terminal according to Embodiment 1 FIG. 1 is a block diagram showing the configuration of a base station according to Embodiment 1; Block diagram showing the configuration of a terminal according to Embodiment 1 Diagram showing a configuration example of RBG FIG. 4 is a diagram showing the flow of the RBG size determination method according to the first embodiment; A diagram showing an example of a method for determining the RBG size according to Embodiment 1 FIG. 11 shows an example of the RBG size determination method according to Modification 1 of Embodiment 1. FIG. FIG. 10 is a diagram showing an example of the RBG size determination method according to Modification 2 of Embodiment 1. FIG. A diagram for explaining the problem of the second embodiment A diagram showing an example of a method for determining the RBG size according to Embodiment 2 A diagram showing an example of an RB grid between numerologies with different subcarrier intervals A diagram showing an example of RB grids and RBGs between numerologies with different subcarrier intervals A diagram showing an example of a method for determining the RBG size according to the third embodiment A diagram showing an example of a method for determining the RBG size according to the fourth embodiment A diagram showing an RBG setting example when the first band and segments are discontinuous on the frequency axis. A diagram showing an example of an RBG determination method according to the fifth embodiment FIG. 11 is a diagram showing an example of the RBG determination method according to the sixth embodiment; A diagram showing an example of a PRG determination method according to Embodiment 7 A diagram showing an example of a PRG determination method according to the eighth embodiment Diagram showing an example of a method for determining a CSI subband size according to Embodiment 9 A diagram showing an example of a method for determining a CSI subband size according to Embodiment 10 A diagram showing an example of a method for determining the SRS subband size according to Embodiment 11 A diagram showing an example of a method for determining the SRS subband size according to the twelfth embodiment

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

In one aspect of the present disclosure, an extended band including BCC and segments is considered as one virtual carrier, and a method for determining operationally necessary parameters for the virtual carrier is described. According to this method, the base station can schedule resource allocation for the expanded band including the BCC after adding the segment and the segment using one downlink control signal. Also, changes from existing resource allocation mechanisms can be kept to a minimum.

(Embodiment 1)
[Outline of communication system]
A communication system according to each embodiment of the present disclosure includes base station 100 and terminal 200 .

FIG. 1 is a block diagram showing the configuration of base station 100 according to each embodiment of the present disclosure. In base station 100 shown in FIG. 1, control section 101 determines parameters (here, RBG size) for a second band (virtual carrier) composed of a first band and a segment that is an additional band for the first band, and transmitting section 113 (corresponding to a transceiver, including signal allocation section 111) uses the parameters to communicate with terminal 200 in the second band.

FIG. 2 is a block diagram showing the configuration of terminal 200 according to each embodiment of the present disclosure. In the terminal 200 shown in FIG. 2, the control unit 208 determines the parameters (RBG size) for the second band (virtual carrier) composed of the first band and the segment that is the additional band for the first band.

In addition, hereinafter, "BCC" or "First RF band" which is a band necessary for terminal 200 to receive a downlink control signal (for example, DCI (Downlink Control Information)) is defined as "first band".

Also, hereinafter, the expanded band including the BCC and the segment after adding the segment to the first band is defined as a 'virtual carrier' or a 'second band'.

[Base station configuration]
FIG. 3 is a block diagram showing the configuration of base station 100 according to Embodiment 1 of the present disclosure. 3, base station 100 includes control section 101, data generation section 102, encoding section 103, modulation section 104, upper control signal generation section 105, encoding section 106, modulation section 107, downlink control signal generation section 108, encoding section 109, modulation section 110, signal allocation section 111, IFFT (Inverse Fast Fourier Transform) section 112, and transmission section 113. , an antenna 114 , a receiving section 115 , an FFT (Fast Fourier Transform) section 116 , an extraction section 117 , a CSI (Channel State Information) demodulation section 118 , and an SRS (Sounding Reference Signal) measurement section 119 .

Control section 101 determines the RBG (Resource Block Group) size for the virtual carrier (second band). At this time, control section 101 outputs information indicating the determined RBG size for the virtual carrier to signal allocation section 111 . Control section 101 may output information indicating the determined RBG size for the virtual carrier to higher control signal generation section 105 .

Also, control section 101 determines information on CSI feedback or SRS, and outputs the determined information to higher control signal generation section 105 and extraction section 117 (details will be described later in Embodiments 9 to 12). Also, when the setting of the RBG (RBG size or RBG delimiter) for the virtual carrier can be changed, control section 101 outputs information on the setting change to upper control signal generating section 105 (details will be described later in Embodiments 4 and 6).

In addition, control section 101, for example, uses the determined RBG to determine radio resource allocation for downlink data for terminal 200, and outputs downlink resource allocation information indicating resource allocation for downlink data to downlink control signal generation section 108 and signal allocation section 111.

Data generation section 102 generates downlink data for terminal 200 and outputs the data to encoding section 103 .

Encoding section 103 performs error correction encoding on the downlink data input from data generating section 102 and outputs the encoded data signal to modulating section 104 .

Modulation section 104 modulates the data signal input from encoding section 103 and outputs the modulated data signal to signal allocation section 111 .

High-level control signal generation section 105 generates a control information bit string using information input from control section 101 and outputs the generated control information bit string to encoding section 106 . In addition, the upper control signal generation unit 105 uses information (e.g., bandwidth) on the first band (BCC or First RF band) and information (e.g., bandwidth) on the segment (additional band) to generate a control information bit string, and outputs the generated control information bit string to the encoding unit 106.

Encoding section 106 performs error correction encoding on the control information bit string input from upper control signal generating section 105 and outputs the encoded control signal to modulating section 107 .

Modulation section 107 modulates the control signal input from encoding section 106 and outputs the modulated control signal to signal allocation section 111 .

Downlink control signal generation section 108 generates a control information bit string using information indicating the RBG size banded to the virtual carrier input from control section 101 and downlink resource allocation information, and outputs the generated control information bit string to encoding section 109. Since control information may be transmitted to a plurality of terminals, downlink control signal generation section 108 may generate a bit string including the terminal ID of each terminal in the control information for each terminal.

Encoding section 109 performs error correction encoding on the control information bit string input from downlink control signal generating section 108 and outputs the encoded control signal to modulating section 110 .

Modulation section 110 modulates the control signal input from encoding section 109 and outputs the modulated control signal to signal allocation section 111 .

Signal allocation section 111 maps data signals input from modulation section 104 to radio resources based on information about RBG input from control section 101 or downlink resource allocation information. Further, signal allocation section 111 maps control signals input from modulation section 107 or modulation section 110 to radio resources. The signal allocation unit 111 outputs the downlink signal to which the signal is mapped to the IFFT unit 112 .

IFFT section 112 performs transmission waveform generation processing such as OFDM (Orthogonal Frequency Division Multiplexing) on the signal input from signal allocation section 111 . The IFFT unit 112 adds a CP (not shown) in the case of OFDM transmission that adds a CP (Cyclic Prefix). IFFT section 112 outputs the generated transmission waveform to transmission section 113 .

Transmitting section 113 performs RF (Radio Frequency) processing such as D/A (Digital-to-Analog) conversion and up-conversion on the signal input from IFFT section 112 , and transmits the radio signal to terminal 200 via antenna 114 .

Receiving section 115 performs RF processing such as down-conversion or A/D (Analog-to-Digital) conversion on the signal waveform or SRS of the CSI feedback signal from terminal 200 received via antenna 114, and outputs the resulting received signal to FFT section 116.

FFT section 116 performs FFT processing for transforming a time domain signal into a frequency domain signal on the received signal input from receiving section 115 . FFT section 116 outputs the frequency domain signal obtained by the FFT processing to extraction section 117 .

Extracting section 117 extracts the radio resource in which the CSI feedback signal or SRS is transmitted from the signal input from FFT section 116 based on the information (CSI feedback-related information or SRS-related information) received from control section 101, and outputs the extracted radio resource components (CSI feedback signal or SRS signal) to CSI demodulating section 118 and SRS measuring section 119, respectively.

CSI demodulation section 118 demodulates the CSI feedback signal input from extraction section 117 and outputs the demodulated information to control section 101 . CSI feedback is used, for example, in control section 101 to control downlink allocation.

SRS measurement section 119 measures uplink channel quality using the SRS signal input from extraction section 117 and outputs the measured information to control section 101 . The measured information is used, for example, in control of uplink allocation in control section 101 (not shown).

[Device configuration]
FIG. 4 is a block diagram showing the configuration of terminal 200 according to Embodiment 1 of the present disclosure. 4, terminal 200 includes antenna 201, receiving section 202, FFT section 203, extracting section 204, downlink control signal demodulation section 205, higher control signal demodulation section 206, downlink data signal demodulation section 207, control section 208, CSI generation section 209, coding section 210, modulation section 211, SRS generation section 212, signal allocation section 213, IFFT section 214, and a transmitter 215 .

The receiving unit 202 performs RF processing such as down-conversion or A/D (Analog-to-Digital) conversion on the signal waveform of the downlink signal (data signal and control signal) from the base station 100 received via the antenna 201, and outputs the obtained received signal (baseband signal) to the FFT unit 203.

FFT section 203 performs FFT processing on the signal (time domain signal) input from receiving section 202 to transform the time domain signal into a frequency domain signal. FFT section 203 outputs the frequency domain signal obtained by the FFT processing to extraction section 204 .

Extraction section 204 extracts the downlink control signal from the signal input from FFT section 203 based on the control information input from control section 208 , and outputs the downlink control signal to downlink control signal demodulation section 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 208, outputs the upper control signal to the upper control signal demodulation unit 206, and outputs the downlink data signal to the downlink data signal demodulation unit 207.

Downlink control signal demodulation section 205 blind-decodes the downlink control signal input from extraction section 204 , and when determining that the control signal is addressed to itself, downlink control signal demodulation section 205 demodulates the control signal and outputs it to control section 208 .

Higher-level control signal demodulation section 206 demodulates the higher-level control signal input from extraction section 204 and outputs the demodulated higher-level control signal to control section 208 .

Downlink data signal demodulation section 207 demodulates the downlink data signal input from extraction section 204 to obtain a demodulated signal.

Control section 208 calculates radio resource allocation for the downlink data signal based on the downlink resource allocation information indicated in the control signal input from downlink control signal demodulation section 205, and outputs information indicating the calculated radio resource allocation to extraction section 204.

In addition, control section 208 sets RBG (RBG size or RBG division) for the virtual carrier (second band) by a method described later, based on the downlink control signal input from downlink control signal demodulation section 205 or the higher control signal input from higher control signal demodulation section 206. Control section 208 then outputs information about the set RBG to extraction section 204 .

In addition, control section 208 sets radio resources for CSI feedback or SRS based on the downlink control signal input from downlink control signal demodulation section 205 or the higher control signal input from higher control signal demodulation section 206, and outputs information about the set CSI feedback or SRS to signal allocation section 213 (details will be described later in Embodiments 9 to 12).

CSI generating section 209 generates a CSI feedback bit sequence using the measurement result of downlink channel quality measured in terminal 200 and outputs the CSI feedback bit sequence to encoding section 210 .

Coding section 210 performs error correction coding on the CSI feedback bit string input from CSI generating section 209 and outputs the coded CSI signal to modulating section 211 .

Modulation section 211 modulates the CSI signal input from encoding section 210 and outputs the modulated CSI signal to signal allocation section 213 .

SRS generation section 212 generates an SRS sequence and outputs it to signal allocation section 213 .

Signal allocation section 213 maps the CSI signal input from modulation section 211 and the SRS sequence input from SRS generation section 212 to radio resources instructed by control section 208 . The signal allocation unit 213 outputs the uplink signal to which the signal is mapped to the IFFT unit 214 .

IFFT section 214 performs transmission waveform generation processing such as OFDM on the signal input from signal allocation section 213 . The IFFT unit 214 adds a CP (not shown) in the case of OFDM transmission that adds a CP (Cyclic Prefix). Alternatively, when the IFFT section 214 generates a single carrier waveform, a DFT (Discrete Fourier Transform) section may be added before the signal allocation section 213 (not shown). The IFFT section 214 outputs the generated transmission waveform to the transmission section 215 .

Transmitting section 215 performs RF (Radio Frequency) processing such as D/A (Digital-to-Analog) conversion and up-conversion on the signal input from IFFT section 214 , and transmits the radio signal to base station 100 via antenna 201 .

[Operation of base station 100 and terminal 200]
Operations in base station 100 and terminal 200 having the above configurations will be described in detail.

In the present embodiment, base station 100 and terminal 200 determine parameters required for communication between base station 100 and terminal 200 for one "virtual carrier" (second band), which is an extended band including the first band and the segment after adding a segment to the first band, in a radio communication system that flexibly supports various bandwidths in LTE-Advanced described above or in a radio communication system that allows flexible changes in the RF bandwidth of terminal 200 in NR.

LTE-Advanced or NR employs OFDM or Single-Carrier Frequency Division Multiple Access (SC-FDMA) for signal waveforms. These signal waveforms realize multiple access between the base station and a plurality of terminals by using different subcarriers for each terminal.

A resource block (RB) is the minimum unit of radio resource allocation, and in LTE-Advanced or NR, consists of 12 subcarriers regardless of subcarrier intervals. However, RBs are not limited to 12 subcarriers, and may be configured with other numbers of subcarriers.

In LTE-Advanced, as a method of allocating RBs to terminals for a downlink data channel (PDSCH: Physical Downlink Shared Channel), there is a method of using a radio resource group unit called a resource block group (RBG). An RBG is composed of a plurality of continuous RBs as shown in FIG. 5 (two RBs in the example of FIG. 5). In LTE-Advanced, the number of resource blocks (RBG size) P included in RBGs is set according to the system bandwidth (see Non-Patent Document 5, for example). For example, the base station may notify the PDSCH resource allocation for the terminal using a downlink control signal (DCI) as a bitmap in units of RBGs. In this case, the greater the number of RBGs, the greater the number of bits of the downlink control signal.

In the present embodiment, base station 100 and terminal 200 determine the size of RBG, which is a parameter applied to PDSCH resource allocation, as a parameter for virtual carriers. Specifically, base station 100 and terminal 200 determine the RBG size for the virtual carrier based on the bandwidth of the virtual carrier (that is, the sum of the bandwidths of the first band and segments).

FIG. 6 shows a flow showing the flow of RBG size determination processing according to the present embodiment.

Base station 100 notifies 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)) in a first band (ST101).

Terminal 200 acquires system information using the first band, and executes a random access procedure or RRC connection control with base station 100 (ST102).

For example, base station 100 may notify terminal 200 of information on the first band (eg, bandwidth) using the system information (eg, MIB). Also, base station 100 may notify terminal 200 of information (eg, bandwidth) on segments (additional bands) using the system information (eg, SIB) or terminal-specific RRC (Radio Resource Control) signals. Note that the number of segments may be plural.

Information about the first band and information about the segment may be notified from base station 100 to terminal 200 by a method other than the above. For example, base station 100 may notify information about segments to terminal 200 using the MIB. At this time, the MIB may be notified to terminal 200 using the first band, or may be notified to terminal 200 using the segment. Also, base station 100 may notify terminal 200 of information on virtual carriers (for example, the total bandwidth of the first band and segments). Also, when the first band and the segment are continuous on the frequency axis, base station 100 notifies terminal 200 of information on the virtual carrier (e.g., total bandwidth), and when the first band and the segment are discontinuous on the frequency axis, base station 100 may notify terminal 200 of information on the segment (e.g., bandwidth) using system information (e.g., SIB) or a terminal-specific RRC signal.

Base station 100 may use MAC signaling, an RRC signal, or a downlink control signal (DCI: Downlink Control Information) in order to notify terminal 200 of segment settings (segment use start and end).

Next, the base station 100 calculates the bandwidth of the virtual carrier, which is an extended band including the first band and the segment, based on the information (bandwidth) on the first band and the information (bandwidth) on the segment (additional band). Base station 100 then determines the RBG size for the virtual carrier based on the calculated bandwidth of the virtual carrier (ST103). Details of the method of determining the RBG size of the virtual carrier will be described later.

Also, similarly to base station 100 (ST101), terminal 200 uses the information (bandwidth) about the first band and the information (bandwidth) about the segment notified from base station 100 in ST101 to calculate the bandwidth of the virtual carrier (that is, the total bandwidth of the first band and the segment). Terminal 200 then determines the RBG size for the virtual carrier based on the calculated bandwidth of the virtual carrier (ST104).

Base station 100 then allocates downlink data (PDSCH) resources in virtual carriers to terminal 200 using the determined RBG size, and transmits downlink resource allocation information and the downlink data (ST105). Terminal 200 identifies the allocated downlink resource based on the determined RBG size and receives downlink data.

7 and 8 show an example of the RBG size determination method according to this embodiment.

In the following, as an example, the same relationship between system bandwidth and RBG size as in LTE is used. Specifically, when the system bandwidth is 10 RBs or less, the RBG size is P=1; when the system bandwidth is 11 RBs to 26 RBs, the RBG size is 2; when the system bandwidth is 27 RBs to 63 RBs, the RBG size is 3; However, the relationship between system bandwidth and RBG size is not limited to the same relationship as in LTE. Also, in LTE, the RBG size is only considered up to 20 MHz (110 RB), but in NR, application of a bandwidth wider than 20 MHz (for example, 80 MHz) is also considered, so if the system bandwidth is wider than 20 MHz, an RBG size larger than P = 4 may be used.

The base station 100 and the terminal 200 determine the RBG size of the virtual carrier based on the bandwidth of the virtual carrier (second band) including the first band and segment, rather than the bandwidth of each of the first band and segment allocated to the terminal 200.

FIG. 7 shows an example where the first band is 5 MHz (25 RB) and the segment is 3 MHz (15 RB). When data is transmitted and received separately in the first band or segment shown in FIG. 7, the RBG size of the first band and segment is P=2 corresponding to 25 RB and 15 RB respectively. On the other hand, since the bandwidth of the virtual carrier shown in FIG. 7 is 8 MHz (40 RB), when data is transmitted and received using the virtual carrier, the RBG size is P=3 corresponding to 40 RB.

FIG. 8 shows an example where the first band is 5 MHz (25 RB) and the segment is 1.4 MHz (6 RB). When individual data is transmitted and received in the first band or segment shown in FIG. 8, the RBG size of the first band is P=2 corresponding to 25 RBs, and the RBG size of the segment is P=1 corresponding to 6 RBs. On the other hand, since the bandwidth of the virtual carrier shown in FIG. 8 is 6.4 MHz (31 RB), when data is transmitted and received using the virtual carrier, the RBG size is P=3 corresponding to 31 RB.

That is, in FIGS. 7 and 8, the RBG size is larger when the RBG size is determined based on the virtual carrier including the first band and segment than when the RBG size is determined based on the individual bandwidths of the first band and segment. Therefore, by determining the RBG size in units of virtual carriers in all the bandwidths (8 MHz or 6.4 MHz) of the first band and segments shown in FIG. 7 or 8, the total number of RBGs set in virtual carriers can be reduced.

As described above, according to the present embodiment, base station 100 and terminal 200 determine the RBG size for a virtual carrier with the virtual carrier including the first band and segment as one unit. As a result, the number of RBGs in the virtual carrier can be reduced, so compared to the case of applying the RBG size when using the first band and segment individually, the number of bits required for resource allocation in the downlink control signal (DCI) can be reduced, and the overhead of resource allocation can be reduced.

That is, according to the present embodiment, for example, in a radio communication system that flexibly supports various bandwidths in LTE-Advanced, or in a radio communication system that allows flexible changes in the RF bandwidth of a terminal in NR, even when a method of adding segments is applied, it is possible to appropriately determine parameters (here, RBG size) required for operation in a flexible bandwidth (for example, virtual carrier).

(Modification 1 of Embodiment 1)
In modification 1, base station 100 and terminal 200 calculate the standard bandwidth that is the next largest after the bandwidth of the first band, and determine the RBG size for the virtual carrier (second band).

Here, standard bandwidths are 1.4 MHz, 3 MHz, 5 MHz, 10 MHz, 15 MHz and 20 MHz in LTE-Advanced. Note that the standard bandwidth is not limited to the above values, and other standard bandwidths may be defined.

For example, in FIG. 9, the next largest standard bandwidth after the bandwidth of the first band (10 MHz: 50 RB) is 15 MHz (75 RB). Therefore, base station 100 and terminal 200 determine the RBG size for the virtual carrier including the first band and segment of 10 MHz to be P=4 corresponding to 15 MHz.

As a result, for example, even when information (bandwidth) about the first band and information (bandwidth) about the segment are notified separately to terminal 200, terminal 200 can determine the RBG size of the virtual carrier from the bandwidth of the first band. That is, according to Modification 1, the method of determining the RBG size can be simplified.

(Modification 2 of Embodiment 1)
In Modification 2, base station 100 and terminal 200 calculate the standard bandwidth having the minimum bandwidth among standard bandwidths larger than the bandwidth of the virtual carrier (second band), and determine the RBG size for the virtual carrier.

For example, among the standard bandwidths larger than the virtual carrier bandwidth (11.4 MHz (56 RB)) shown in FIG. 9, the standard bandwidth having the smallest bandwidth is 15 MHz (75 RB). Therefore, base station 100 and terminal 200 determine the RBG size for virtual carriers to be P=4 corresponding to 15 MHz.

By this means, base station 100 and terminal 200 can simplify the method of determining the RBG size by determining the RBG size for a virtual carrier in the same manner as the standard bandwidth that approximates the bandwidth of the virtual carrier.

Further, according to Modifications 1 and 2 of Embodiment 1, by setting the bandwidth for resource allocation to be the same as the standard bandwidth used when determining the RBG, the resource allocation region in DCI can be made the same as the standard bandwidth, so DCI decoding in terminal 200 can be simplified.

(Embodiment 2)
Embodiment 1 describes the case where the RBG size of the virtual carrier is determined based on the bandwidth of the virtual carrier (second band), whereas this embodiment describes the case of determining the RBG size of the virtual carrier based on the RBG size of the first band (for example, BCC).

Here, when a terminal that transmits/receives data using the first band and a terminal that transmits/receives data using a virtual carrier coexist within the same resource, there is a possibility that the resource cannot be used efficiently.

FIG. 10 shows an example where the first band is 5 MHz (25 RB) and the segment is 3 MHz (15 RB). In FIG. 10, as in Embodiment 1, it is assumed that the RBG size is determined according to the system bandwidth.

In FIG. 10, when individual data is transmitted and received using the first band or segment, the RBG size of the first band and segment is P=2, respectively. On the other hand, since the bandwidth of the virtual carrier is 8 MHz (40 RB), when data is transmitted and received using the virtual carrier, the RBG size of the virtual carrier is P=3.

At this time, as shown in FIG. 10, when a terminal that transmits/receives data using the first band (referred to as "terminal #1") and a terminal that transmits/receives data using a virtual carrier (referred to as "terminal #2") coexist, when terminal #1 is assigned RBG#2 (RB#3, RB#4), RB#3 and #4 are included for terminal #2. 6) can no longer be assigned. In other words, in FIG. 10, one RBG allocated to terminal #1 is set across resources corresponding to two RBGs for terminal #2, so the efficiency of resource allocation to terminal #2 deteriorates.

Therefore, in this embodiment, the RBG size for the virtual carrier is determined in consideration of the RBG size of the first band.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on the segment (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, so description thereof will be omitted here.

Base station 100 according to the present embodiment calculates the bandwidth of the virtual carrier (that is, the total bandwidth of the first band and the segment) based on the information (bandwidth) on the first band and the information (bandwidth) on the segment (additional band). Also, terminal 200 calculates the bandwidth of the virtual carrier (second band) based on the information (bandwidth) on the first band and the information (bandwidth) on the segment notified from base station 100 .

Also, in the present embodiment, base station 100 and terminal 200 determine the RBG size to be set in the virtual carrier to be X times the RBG size set based on the bandwidth of the first band (where X is an integer equal to or greater than 2). Information about X may be notified from base station 100 to terminal 200, or may be a value determined by a standard.

FIG. 11 shows an example of an RBG size determination method according to this embodiment.

FIG. 11 shows an example where the first band is 5 MHz (25 RB), the segment is 3 MHz (15 RB), and the bandwidth of the virtual carrier is 8 MHz (40 RB). When individual data is transmitted and received in the first band or segment shown in FIG. 11, the RBG size of the first band and segment is P=2 corresponding to 25 RBs and 15 RBs, respectively.

In FIG. 11, X=2. Therefore, the RBG size when data is transmitted and received using the virtual carrier shown in FIG. 11 is P=4, which is X times the RBG size P=2 set based on the bandwidth of the first band. By doing this, the RBG boundary (delimiter) set for the virtual carrier matches the RBG boundary set based on the width of the first band. This allows the base station 100 to efficiently allocate resources to the terminal 200 that transmits and receives data using virtual carriers.

For example, in FIG. 11, when a terminal that transmits/receives data using the first band and a terminal that transmits/receives data using a virtual carrier coexist in the same resource, RBG#2 (RB#3, RB#4) is assigned to the terminal that transmits/receives data using the first band. In this case, base station 100 cannot allocate RBG#1 (RB#1 to #4) including RB#3 and #4 to terminals that transmit and receive data using virtual carriers. In other words, one RBG assigned to a terminal that transmits/receives data using the first band does not allocate two RBGs to a terminal that transmits/receives data using a virtual carrier in the example shown in FIG.

In this way, in the present embodiment, by setting the RBG size for a virtual carrier to an integral multiple of the RBG size set based on the bandwidth of the first band, it is possible to prevent the RBG assigned to a terminal that transmits and receives data using the first band from being set across resources corresponding to multiple RBGs for terminals that transmit and receive data using a virtual carrier. As a result, a terminal that transmits and receives data using the first band and a terminal that transmits and receives data using the virtual carrier can be efficiently multiplexed.

Also, according to the present embodiment, an RBG size larger than the RBG size of the first band can be set for virtual carriers. As a result, as in Embodiment 1, when using virtual carriers, the number of RBGs in virtual carriers can be reduced compared to the case where the RBG size of the first band is applied as it is. Therefore, the number of bits required for resource allocation in the downlink control signal (DCI) can be reduced, and the overhead of resource allocation can be reduced.

(Embodiment 3)
In NR, mixed numerology, in which signal waveforms with different subcarrier intervals and the like are mixed in the same band, is being studied as a method of accommodating terminals for services with different requirements. Also, in NR, RBs are being considered to be configured with 12 subcarriers regardless of subcarrier spacing. Also, in 3GPP, when performing FDM on Numerology with different subcarrier intervals, it is agreed that the RB grid of each subcarrier interval should be a nested structure as shown in FIG. Note that the allocation of RB numbers shown in FIG. 12 is an example, and is not limited to this.

Also, FIG. 13 shows an example of an RB grid when multiplexing terminals with subcarrier intervals of 15 kHz, 30 kHz and 60 kHz. As shown in FIG. 13, when terminals with different subcarrier intervals coexist, if the RBG size is set to a power of 2, the RBG boundaries (delimiters) and RB grid boundaries can be aligned between Numerologies with different subcarrier intervals, so resources can be used efficiently.

Therefore, in this embodiment, the RBG size for the virtual carrier is also set to a power of two.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on the segment (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, so description thereof will be omitted here.

Base station 100 according to the present embodiment calculates the bandwidth of the virtual carrier (that is, the sum of the bandwidths of the first band and the segments) based on the information (bandwidth) about the first band and the information (bandwidth) about the segment (additional band). Also, terminal 200 calculates the bandwidth of the virtual carrier (second band) based on the information (bandwidth) on the first band and the information (bandwidth) on the segment notified from base station 100 .

Also, with the present embodiment, base station 100 and terminal 200 determine the power of 2 as the RBG size set in the virtual carrier. Information on the RBG size (for example, the power of 2: the value of n in ²ⁿ ) may be notified from base station 100 to terminal 200, or may be a value determined by the standard. Also, as in Embodiment 1, the RBG size (for example, the power of 2: the value of ⁿ in 2n) may be calculated from the bandwidth of the virtual carrier.

FIG. 14 shows an example of an RBG size determination method according to this embodiment.

FIG. 14 shows an example in which the RBG size P=2 of the first band with 15 kHz subcarrier spacing and the RBG size P=2 of the virtual carrier with 30 kHz subcarrier spacing. That is, in FIG. 14, the RBG size of the virtual carrier is 2 1 . By doing so, the RBG boundary (delimiter) set for the virtual carrier matches the RBG boundary set based on the width of the first band. This allows the base station 100 to efficiently allocate resources to the terminal 200 that transmits and receives data using virtual carriers.

For example, in FIG. 14, when a terminal that transmits/receives data using the first band and a terminal that transmits/receives data using a virtual carrier coexist in the same resource, RBG#2 (RB#3, RB#4) is assigned to the terminal that transmits/receives data using the first band. In this case, base station 100 cannot allocate RBG#1 (RB#1, #2) including the same resources as RB#3, #4 at 15 kHz subcarrier intervals to terminals that transmit and receive data using virtual carriers. In other words, as shown in FIG. 14, only one RBG cannot be assigned to a terminal that performs transmission/reception using virtual carriers.

In this manner, in this embodiment, by setting the RBG size for virtual carriers to a power of 2, even when terminals with different subcarrier intervals coexist, RBG boundaries can be aligned between terminals, so that multiple terminals with different subcarrier intervals can be efficiently multiplexed.

That is, according to the present embodiment, for example, in a radio communication system that flexibly supports various bandwidths in LTE-Advanced, or in a radio communication system that allows flexible changes in the RF bandwidth of terminals in NR, even when terminals with different subcarrier intervals are mixed, it is possible to appropriately determine parameters (here, RBG size) required for operation in a flexible bandwidth (for example, virtual carrier).

(Embodiment 4)
Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here.

This embodiment will explain a case where the RBG size for a virtual carrier (second band) is adaptively changed by signaling from base station 100 to terminal 200 .

Control section 101 of base station 100 variably sets the RBG size for virtual carriers according to the communication status of terminal 200, for example. For example, when base station 100 needs to multiplex a terminal that transmits and receives data using the first band and a terminal that transmits and receives data using a virtual carrier, the RBG size of the virtual carrier is determined to be the same as the first band, an integral multiple of the first band, or a power of 2 (see, for example, Embodiments 2 and 3). On the other hand, if base station 100 does not need to multiplex terminals that transmit and receive data using the first band, the RBG size of the virtual carrier may be set to a value other than an integral multiple (or the same value) as that of the first band.

Then, base station 100 notifies terminal 200 of information on the RBG size for virtual carriers (information on setting change) using higher control signals (for example, system information (MIB or SIB) or RRC signals).

Terminal 200 receives the higher control signal notified from base station 100 and identifies the RBG size for the virtual carrier based on the received higher control signal.

FIG. 15 shows an example of an RBG size determination method according to this embodiment. FIG. 15 shows an example in which the virtual carrier RBG size can be set to either P=3 or P=4.

For example, in FIG. 15, when terminals that transmit and receive using a first band with an RBG size of P=2 (see, for example, FIG. 10) and terminals that transmit and receive using virtual carriers are mixed, base station 100 may notify terminals that transmit and receive using virtual carriers of an RBG size of P=4 (or the square of 2), which is twice the RBG size P=2, as shown in the lower diagram of FIG. By this means, as in Embodiments 2 and 3, base station 100 can efficiently multiplex terminals that transmit and receive data using the first band and terminals that transmit and receive data using virtual carriers.

On the other hand, if there is no terminal that performs transmission/reception using the first band that is multiplexed with the terminal that performs transmission/reception using the virtual carrier, base station 100 may notify the terminal that performs transmission/reception using the virtual carrier of the RBG size P=3. As a result, for example, as in Embodiment 1 (see FIG. 7), the RBG size is determined according to the bandwidth of the virtual carrier, and resource allocation can be performed flexibly while reducing resource allocation overhead.

Thus, according to the present embodiment, the RBG size set in the virtual carrier is variable, and the RBG size is notified from base station 100 to terminal 200 by signaling (eg, system information (MIB, SIB) or RRC signal). As a result, for example, the RBG size of the virtual carrier for the terminal 200 can be adaptively changed depending on whether or not it is necessary to multiplex the terminal that transmits and receives data using the first band and the terminal that transmits and receives data using the virtual carrier.

Note that terminal 200 may reset the RBG size using an RRC signal even when the RBG size is notified by system information (for example, MIB or SIB).

Alternatively, when the RBG size is notified by an RRC signal, terminal 200 may use the Default RBG size until receiving the RRC signal. The default RBG size may be notified by system information, or may be determined in the same manner as in the first to third embodiments.

(Embodiment 5)
In the present embodiment, a method for determining RBs forming an RBG, which is a parameter applied to downlink data channel (PDSCH) resource allocation, will be described.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on the segment (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, so description thereof will be omitted here. Also, any one of the methods of Embodiments 1 to 4 may be used as the method of determining the RBG size.

Also, as described in Embodiments 1 to 4 above, when the band including the first band and the segment is regarded as one virtual carrier (second band) and the RBG size is determined, as shown in FIG. At this time, as shown in FIG. 16, when the first band and the segment are discontinuous on the frequency axis (when there is a gap on the frequency axis), multiple RBs with different channel states are treated as one RBG (RBG#9). Therefore, it is expected that the scheduling for the RBG, precoding setting, channel estimation accuracy, etc. will be adversely affected.

Therefore, with the present embodiment, a case will be described where the RBs that make up one RBG are configured either from the RBs of the first band or the RBs of the segment. That is, in the present embodiment, base station 100 and terminal 200 set RBGs so that the boundaries (delimiters) of RBGs set in virtual carriers and the boundaries between the first band and segments included in the virtual carriers match.

FIG. 17 shows an example of an RBG determination method according to this embodiment. In FIG. 17, the RBG size P=3.

In FIG. 17, the first band and segments are discontinuous on the frequency axis. In FIG. 17, RBG#1 to #9 are composed of RBs of the first band (RB#1 to RB#25), and RBG#10 to #14 are composed of segment RBs (RB#1 to RB#15).

As shown in FIG. 17, near the boundary between the first band and the segment in the virtual carrier, one RB#25 of the first band constitutes RBG#9, and three RB#1 to #3 of the segment constitute RBG#10. That is, in FIG. 17, the RBG boundary coincides with at least the boundary between the first band and the segment. In other words, in FIG. 17, there is no RBG made up of resource blocks of both the first band and segment that are discontinuous on the frequency axis. As a result, since the RBs in each RBG shown in FIG. 17 are continuous on the frequency axis, the channel states are approximately the same.

Therefore, in the present embodiment, even when the first band and the segment are discontinuous on the frequency axis, it is possible to suppress the influence of gaps on the frequency axis on scheduling, precoding settings, channel estimation accuracy, etc. for RBGs set in virtual carriers.

(Embodiment 6)
In the present embodiment, a method for determining RBs forming an RBG, which is a parameter applied to downlink data channel (PDSCH) resource allocation, will be described.

The effect of the gap on the frequency axis described in Embodiment 5 occurs when the first band and the segment are discontinuous on the frequency axis.

On the other hand, when the first band and the segment are continuous on the frequency axis, rather than aligning the RBG boundary with the boundary between the first band and the segment as in Embodiment 5, it is possible to simplify the processing and reduce the number of RBGs by constructing the RBG without being aware of the boundary between the first band and the segment. As a result, the number of bits required for resource allocation in DCI can be reduced, and the overhead of resource allocation can be reduced.

Therefore, with the present embodiment, a case will be described where the settings of RBs forming an RBG are adaptively changed.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here. Also, any one of the methods of Embodiments 1 to 4 may be used as the method of determining the RBG size.

FIG. 18 shows an example of an RBG determination method according to this embodiment. FIG. 18 assumes that the RBG size of the virtual carrier is P=3.

Base station 100 (control section 101) sets RBGs without regard to the boundary between the first band and the segment when the first band and segment forming the virtual carrier are continuous on the frequency axis. For example, as shown in the upper diagram of FIG. 18, there is RBG#9 composed of both RBs of the first band (RB#25) and segment RBs (RB#1, #2). Depending on the bandwidth of the first band and segment, there may be no RBG including RBs of both the first band and segment, such as RBG#9 in the upper diagram of FIG.

On the other hand, when the first band and the segment included in the virtual carrier are discontinuous on the frequency axis, base station 100 (control section 101) sets the RBG such that the boundary between the RBG and the boundary between the first band and segment coincides, as in Embodiment 5. For example, as shown in the lower diagram of FIG. 18, each RBG is composed of either the RBs of the first band or the RBs of the segments, and there is no RBG composed of both the RBs of the first band and the RBs of the segments.

Then, base station 100 notifies terminal 200 of information on RBG boundaries for virtual carriers (information on setting changes) using higher control signals (for example, system information (MIB or SIB) or RRC signals).

Terminal 200 receives the higher control signal notified from base station 100, and specifies the setting of RBGs (RBs constituting RBGs) for virtual carriers based on the received higher control signal.

Although a case has been described where RBGs are adaptively set by signaling (for example, system information (MIB, SIB) or RRC signal) from base station 100 to terminal 200, base station 100 and terminal 200 may adaptively set RBGs (RBs constituting RBGs) set in virtual carriers based on the relationship on the frequency axis between the first band and segments included in virtual carriers for terminal 200.

Also, in the above description, the RBG is set according to whether the first band and the segment are continuous or discontinuous on the frequency axis, but the RBG setting method is not limited to this. For example, as long as the gap on the frequency axis between the first band and the segment is large enough (e.g., equal to or less than a threshold value) that does not affect scheduling, precoding settings, channel estimation accuracy, etc., the RBG may be set in the same manner as when the first band and the segment are continuous on the frequency axis.

In this manner, according to the present embodiment, the RBG configuration is changed according to the continuity on the frequency axis between the first band and the segment that configure the virtual carrier. As a result, according to the continuity of the first band and the segment on the frequency axis, it is possible to further reduce the overhead of resource allocation while suppressing the influence of gaps on the RBG on the frequency axis.

(Embodiment 7)
Embodiments 1 to 6 have described the method of determining the RBG (RBG size), which is a parameter applied to resource allocation of the downlink data channel (PDSCH). In contrast, with the present embodiment, a method of determining RBs that constitute a precoding group (PRG), which is another parameter applied to PDSCH resource allocation, will be described.

In LTE-Advanced, as a method of setting precoding for terminals for PDSCH, there is a method of using a radio resource group unit called PRG. A PRG, like an RBG, is composed of a plurality of consecutive RBs. In LTE-Advanced, the number of RBs included in PRG is determined according to the system bandwidth (see Non-Patent Document 5, for example).

Therefore, in this embodiment, the PRG size is determined using a method similar to the RBG size determination method described in the first to fourth embodiments. That is, in this embodiment, the PRG size can be determined by replacing "RBG" described in Embodiments 1 to 4 with "PRG".

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here.

That is, in base station 100 according to the present embodiment, control section 101 determines parameters (here, PRG size) for a virtual carrier composed of a first band and a segment that is an additional band for the first band, and transmitting section 113 (corresponding to a transceiver) uses the parameters to communicate with terminal 200 in the second band. Further, in terminal 200 according to the present embodiment, control section 208 determines parameters (PRG size) for a virtual carrier composed of a first band and a segment that is an additional band for the first band, and receiving section 202 (corresponding to a transceiver) uses the parameters to communicate with base station 100 in the second band.

Thus, according to the present embodiment, for example, in a wireless communication system that flexibly supports various bandwidths in LTE-Advanced, or in a wireless communication system that allows flexible changes in the RF bandwidth of a terminal in NR, even when a method of adding segments is applied, it is possible to appropriately determine parameters (here, PRG size) required for operation in a flexible bandwidth (for example, virtual carrier).

Also, when determining a PRG by regarding a band including the first band and segments as one virtual carrier (second band), there is a possibility that a PRG including both the RBs of the first band and the RBs of the segments is configured. At this time, if the first band and the segment are discontinuous on the frequency axis (if there is a gap on the frequency axis), multiple RBs with different channel states will be treated as one PRG. Therefore, it is expected that precoding settings for the PRG, channel estimation accuracy, etc. will be adversely affected.

Therefore, in the present embodiment, as shown in FIG. 19, RBs that make up one PRG are either RBs of the first band or RBs of segments. That is, in the present embodiment, base station 100 and terminal 200 set PRGs so that the boundaries (delimiters) of PRGs set in virtual carriers and the boundaries between the first band and segments included in the virtual carriers match.

For example, as shown in FIG. 19, near the boundary between the first band and the segment in the virtual carrier, one RB#25 of the first band constitutes PRG#9, and three RB#1 to #3 of the segment constitute PRG#10. That is, in FIG. 19, the boundary of the PRG coincides with at least the boundary between the first band and the segment. In other words, in FIG. 19, there is no PRG made up of resource blocks in both the first band and segment that are discontinuous on the frequency axis. As a result, since the RBs in each PRG shown in FIG. 19 are continuous on the frequency axis, the channel states are approximately the same.

Therefore, in the present embodiment, even when the first band and the segment are discontinuous on the frequency axis, it is possible to suppress the effects of gaps on the frequency axis on precoding settings for PRGs set in virtual carriers, channel estimation accuracy, and the like.

(Embodiment 8)
With the present embodiment, a method of determining RBs forming a PRG, which is a parameter applied to resource allocation of a downlink data channel (PDSCH), will be described.

The effect of the gap on the frequency axis described in Embodiment 7 occurs when the first band and the segment are discontinuous on the frequency axis.

On the other hand, when the first band and the segment are continuous on the frequency axis, the processing can be simplified by constructing the PRG without being aware of the boundary between the first band and the segment, rather than aligning the boundary of the PRG with the boundary between the first band and the segment as in Embodiment 7. For example, as described in Embodiment 6 (for example, the RBG in the upper diagram of FIG. 18), when the PBG is configured without being aware of the boundary between the first band and the segment, similarly, if the PRG is configured without being aware of the boundary between the first band and the segment, RBG allocation and precoding setting are simplified.

Therefore, with the present embodiment, a case will be described where the settings of RBs forming a PRG are adaptively changed.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here. Also, as the PRG size determination method, any of the RBG size determination methods described in the first to fourth embodiments may be used. That is, in this embodiment, the PRG size can be determined by replacing "RBG" described in the first to fourth embodiments with "PRG".

FIG. 20 shows an example of a PRG determination method according to this embodiment. In FIG. 20, the PRG size of the virtual carrier is 3 (3 RB).

If the first band and segments are continuous on the frequency axis, base station 100 (control section 101) sets the PRG regardless of the boundary between the first band and segments. For example, as shown in the upper diagram of FIG. 20, there is a PRG#9 composed of both the first band RB (RB#25) and the segment RBs (RB#1, #2). Depending on the bandwidth of the first band and segment, there may be no PRG that includes RBs of both the first band and segment, such as RBG#9 in the upper diagram of FIG.

On the other hand, base station 100 (control section 101) sets the PRG such that the boundary of the PRG and the boundary between the first band and the segment match, as in Embodiment 7, when the first band and the segment included in the virtual carrier are discontinuous on the frequency axis. For example, as shown in the lower diagram of FIG. 20, each PRG is composed of either the RBs of the first band or the RBs of the segments, and there is no PRG composed of both the RBs of the first band and the RBs of the segments.

Then, base station 100 notifies terminal 200 of information on PRG boundaries for virtual carriers (information on setting changes) using higher control signals (for example, system information (MIB or SIB) or RRC signals).

The terminal 200 receives the higher control signal notified from the base station 100, and specifies the setting of the PRG (RBs forming the PRG) for the virtual carrier based on the received higher control signal.

Although a case has been described where PRG is adaptively set by signaling (for example, system information (MIB, SIB) or RRC signal) from base station 100 to terminal 200, base station 100 and terminal 200 may adaptively set PRG (RBs constituting PRG) set in virtual carrier based on the relationship on the frequency axis between the first band and segment included in virtual carrier for terminal 200.

In this manner, according to the present embodiment, the configuration of the PRG is changed according to the continuity on the frequency axis between the first band and the segment forming the virtual carrier. This makes it possible to simplify the processing while suppressing the influence of the gap on the frequency axis on the PRG according to the continuity of the first band and the segment on the frequency axis.

(Embodiment 9)
Embodiments 1 to 8 have described methods of determining RBG or PRG, which are parameters applied to resource allocation of the downlink data channel (PDSCH). On the other hand, in the present embodiment, a method of determining parameters necessary for a terminal to feed back channel state information (CSI: Channel State Information) for a virtual carrier (second band) to a base station will be described.

In LTE-Advanced, CSI feedback information includes a wideband CQI (Channel Quality Indicator) whose feedback bandwidth is a wideband (entire band) and a subband CQI whose feedback bandwidth is a subband unit. A subband (sometimes referred to as a "CSI subband") is composed of a plurality of consecutive RBs, similar to RBGs or PRGs. In LTE-Advanced, the number of RBs included in a CSI subband is determined according to the system bandwidth (see Non-Patent Document 5, for example).

Therefore, in this embodiment, the CSI subband size is determined using a method similar to the RBG size determination method described in Embodiments 1-4. That is, in this embodiment, the CSI subband size can be determined by replacing "RBG" described in Embodiments 1 to 4 with "CSI subband".

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here.

That is, in base station 100 according to the present embodiment, control section 101 determines a parameter (CSI subband size here) for a virtual carrier composed of a first band and a segment that is an additional band for the first band, and receiving section 115 (corresponding to a transceiver, including extraction section 117) uses the parameters to communicate with terminal 200 (receive CSI feedback) in the second band. Further, in terminal 200 according to the present embodiment, control section 208 determines parameters (CSI subband size) for a virtual carrier composed of a first band and a segment that is an additional band for the first band, and transmitting section 215 (corresponding to a transceiver, including signal allocation section 213) uses the parameters to communicate with base station 100 (transmit CSI feedback) in the second band.

Thus, according to the present embodiment, for example, in a wireless communication system that flexibly supports various bandwidths in LTE-Advanced, or in a wireless communication system that allows flexible changes in the RF bandwidth of a terminal in NR, even when a method of adding a segment is applied, it is possible to appropriately determine parameters (here, CSI subband size) required for operation in a flexible bandwidth (for example, virtual carrier).

Also, when determining a CSI subband by regarding a band including a first band and a segment as one virtual carrier (second band), a CSI subband including both RBs of the first band and RBs of a segment may be configured. At this time, if the first band and the segment are non-contiguous on the frequency axis (if there is a gap on the frequency axis), multiple RBs with different channel states will be treated as one CSI subband. Therefore, highly accurate CSI feedback becomes difficult even if the CSI subband is used.

Therefore, in the present embodiment, as shown in FIG. 21, RBs that make up one CSI subband are either RBs of the first band or RBs of a segment. That is, in the present embodiment, base station 100 and terminal 200 set CSI subbands such that the boundary (delimiter) of the CSI subbands set in the virtual carrier coincides with the boundary between the first band and the segment included in the virtual carrier.

For example, as shown in FIG. 21, near the boundary between the first band and the segment in the virtual carrier, one RB#25 of the first band constitutes CSI subband #9, and three segments RB#1 to #3 constitute CSI subband #10. That is, in FIG. 21, the boundaries of the CSI subbands coincide at least with the boundaries between the first band and the segments. In other words, in FIG. 21, there are no CSI subbands composed of resource blocks of both the first band and segments that are discontinuous on the frequency axis. As a result, since the RBs in each CSI subband shown in FIG. 21 are continuous on the frequency axis, the channel states are approximately the same.

Therefore, in the present embodiment, even when the first band and the segment are discontinuous on the frequency axis, it is possible to suppress the influence of the gap on the frequency axis on the CSI feedback accuracy using the CSI subbands set in the virtual carrier.

Note that when terminal 200 is set to a mode using wideband CQI, the bandwidth of wideband CQI may be set for each of the first band and segment.

(Embodiment 10)
This embodiment will explain a method of determining RBs that constitute CSI subbands, which are parameters necessary for a terminal to feed back CSI for a virtual carrier to a base station.

The effect of the gap on the frequency axis described in Embodiment 9 occurs when the first band and the segment are discontinuous on the frequency axis.

On the other hand, when the first band and the segment are continuous on the frequency axis, the processing can be simplified by configuring the CSI subbands without considering the boundary between the first band and the segment, rather than aligning the boundary of the CSI subband with the boundary between the first band and the segment as in Embodiment 9.

Therefore, with the present embodiment, a case will be described where the settings of RBs that make up a CSI subband are adaptively changed.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here. Also, any one of the RBG size determination methods described in Embodiments 1 to 4 may be used as the CSI subband size determination method. That is, in this embodiment, the CSI subband size can be determined by replacing "RBG" described in Embodiments 1 to 4 with "CSI subband".

FIG. 22 shows an example of a CSI subband determination method according to this embodiment. FIG. 22 assumes that the CSI subband size of the virtual carrier is 3 (3 RB).

If the first band and segments are continuous on the frequency axis, base station 100 (control section 101) sets CSI subbands without regard to the boundary between the first band and segments. For example, as shown in the upper diagram of FIG. 22, there is a CSI subband #9 composed of both the first band RB (RB#25) and the segment RBs (RB#1, #2). Depending on the bandwidth of the first band and segments, there may be no CSI subband that includes RBs of both the first band and segments, such as CSI subband #9 in the upper diagram of FIG.

On the other hand, when the first band and the segment included in the virtual carrier are discontinuous on the frequency axis, base station 100 (control section 101) sets the CSI subband such that the boundary between the CSI subbands and the boundary between the first band and the segment coincide as in Embodiment 9. For example, as shown in the lower diagram of FIG. 22 , each CSI subband is composed of either the RBs of the first band or the RBs of the segments, and there is no CSI subband composed of both the RBs of the first band and the RBs of the segments.

Then, base station 100 notifies terminal 200 of information on CSI subband boundaries for virtual carriers (information on setting changes) using higher control signals (for example, system information (MIB or SIB) or RRC signals).

Terminal 200 receives the higher control signal notified from base station 100, and specifies the setting of CSI subbands (RBs constituting CSI subbands) for virtual carriers based on the received higher control signal.

Although a case has been described in which CSI subbands are adaptively set by signaling (for example, system information (MIB, SIB) or RRC signal) from base station 100 to terminal 200, base station 100 and terminal 200 may adaptively set CSI subbands (RBs constituting CSI subbands) set in virtual carriers based on the relationship on the frequency axis between the first band and segments included in virtual carriers for terminal 200.

In this way, according to the present embodiment, the configuration of the CSI subbands is changed according to the continuity on the frequency axis between the first band and the segments that make up the virtual carrier. This makes it possible to simplify the processing while suppressing the influence of the gap on the frequency axis on the CSI feedback accuracy according to the continuity of the first band and the segment on the frequency axis.

(Embodiment 11)
Embodiments 1 to 10 have described the method of determining RBG and PRG, which are parameters applied to resource allocation of the downlink data channel (PDSCH), or CSI that the terminal feeds back to the base station. In contrast, in the present embodiment, a method of determining parameters necessary for a terminal to transmit a sounding reference signal (SRS) for a virtual carrier (second band) to a base station will be described.

In LTE-Advanced, a terminal can transmit an SRS as a reference signal for uplink channel quality measurement. SRS transmission methods include wideband SRS in which the bandwidth is a wideband (full band) and subband SRS in which the bandwidth is in units of subbands. A subband (sometimes referred to as an “SRS subband”) is composed of consecutive multiple RBs, similar to RBG, PRG or CSI subbands. In LTE-Advanced, the number of RBs included in the SRS subbands is determined according to the system bandwidth (see Non-Patent Document 6, for example).

Therefore, in this embodiment, the SRS subband size is determined using a method similar to the RBG size determination method described in Embodiments 1 to 4. That is, in the present embodiment, the SRS subband size can be determined by replacing "RBG" explained in Embodiments 1 to 4 with "SRS subband".

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here.

That is, in base station 100 according to the present embodiment, control section 101 determines parameters (here, SRS subband size) for a virtual carrier composed of a first band and a segment that is an additional band for the first band, and receiving section 115 (corresponding to a transceiver, including extraction section 117) uses the parameters to communicate (receive SRS) with terminal 200 in the second band. Further, in terminal 200 according to the present embodiment, control section 208 determines parameters (SRS subband size) for a virtual carrier composed of a first band and a segment that is an additional band for the first band, and transmitting section 215 (corresponding to a transceiver, including signal allocation section 213) uses the parameters to communicate (SRS transmission) with base station 100 in the second band.

As a result, according to the present embodiment, for example, in a radio communication system that flexibly supports various bandwidths in LTE-Advanced, or in a radio communication system that allows flexible changes in the RF bandwidth of terminals in NR, even when a method of adding segments is applied, it is possible to appropriately determine parameters (here, SRS subband size) required for operation in a flexible bandwidth (for example, virtual carrier).

Also, when the SRS subband is determined by regarding the band including the first band and the segment as one virtual carrier (second band), the SRS subband including both the RB of the first band and the RB of the segment may be configured. At this time, if the first band and the segment are discontinuous on the frequency axis (if there is a gap on the frequency axis), multiple RBs with different channel states will be treated as one SRS subband. Therefore, it is difficult for base station 100 to perform highly accurate channel quality measurement even if the SRS subband is used.

Therefore, in the present embodiment, as shown in FIG. 23, RBs that make up one SRS subband are either RBs of the first band or segment RBs. In other words, in the present embodiment, base station 100 and terminal 200 set SRS subbands such that the boundary (delimiter) of the SRS subbands set in the virtual carrier and the boundary between the first band and the segment included in the virtual carrier match.

For example, as shown in FIG. 23, near the boundary between the first band and the segment in the virtual carrier, one RB#25 of the first band constitutes SRS subband #9, and three RB#1 to #3 of the segment constitute SRS subband #10. That is, in FIG. 23, the boundaries of the SRS subbands coincide at least with the boundaries between the first band and the segments. In other words, in FIG. 23, there is no SRS subband composed of resource blocks of both the first band and the segment that are discontinuous on the frequency axis. As a result, the RBs in each SRS subband shown in FIG. 23 are continuous on the frequency axis, so the channel states are approximately the same.

Therefore, in the present embodiment, even when the first band and the segment are discontinuous on the frequency axis, it is possible to suppress the influence of the gap on the frequency axis on the accuracy of channel quality measurement using the SRS subbands set in the virtual carrier.

Note that when terminal 200 is set to a mode using wideband SRS, the bandwidth of wideband SRS may be set for each of the first band and segment.

(Embodiment 12)
This embodiment will explain a method for determining RBs that constitute SRS subbands, which are parameters necessary for a terminal to transmit SRS for a virtual carrier to a base station.

The effect of the gap on the frequency axis described in Embodiment 11 occurs when the first band and the segment are discontinuous on the frequency axis.

On the other hand, when the first band and the segment are continuous on the frequency axis, the processing can be simplified by configuring the SRS subbands without considering the boundary between the first band and the segment, rather than aligning the boundary of the SRS subband with the boundary between the first band and the segment as in Embodiment 11.

Therefore, with the present embodiment, a case will be described where the settings of RBs that make up the SRS subbands are adaptively changed.

Since the base station and terminal according to this embodiment have the same basic configuration as base station 100 and terminal 200 according to Embodiment 1, they will be described with reference to FIGS.

The method by which base station 100 notifies terminal 200 of information (bandwidth) on the first band and the information (bandwidth) on segments (additional band), and the method by which base station 100 sets (starts and ends use of) segments in terminal 200 are the same as those in Embodiment 1, and thus descriptions thereof are omitted here. Also, any of the RBG size determination methods described in Embodiments 1 to 4 may be used as the SRS subband size determination method. That is, in the present embodiment, the SRS subband size can be determined by replacing "RBG" described in Embodiments 1 to 4 with "SRS subband".

FIG.24 shows an example of a method for determining SRS subbands according to this embodiment. In FIG. 24, the SRS subband size of the virtual carrier (second band) is 3 (3 RB).

If the first band and segments are continuous on the frequency axis, base station 100 (control section 101) sets SRS subbands without regard to the boundaries between the first band and segments. For example, as shown in the upper diagram of FIG. 24, there is a CSI subband #9 composed of both the first band RB (RB#25) and the segment RBs (RB#1, #2). Depending on the bandwidth of the first band and segments, there may be no CSI subband including RBs of both the first band and segments, such as CSI subband #9 in the upper diagram of FIG.

On the other hand, when the first band and the segment included in the virtual carrier are discontinuous on the frequency axis, base station 100 (control section 101) sets the SRS subbands so that the boundary between the SRS subbands and the boundary between the first band and the segment coincide, as in Embodiment 11. For example, as shown in the lower diagram of FIG. 24 , each SRS subband is composed of either the RBs of the first band or the RBs of the segments, and there is no SRS subband composed of both the RBs of the first band and the RBs of the segments.

Then, base station 100 notifies terminal 200 of information on boundaries of SRS subbands for virtual carriers (information on setting changes) using higher control signals (for example, system information (MIB or SIB) or RRC signals).

Terminal 200 receives the higher control signal notified from base station 100, and specifies setting of SRS subbands (RBs constituting SRS subbands) for virtual carriers based on the received higher control signal.

Although the case where the SRS subband is adaptively set by signaling (for example, system information (MIB, SIB) or RRC signal) from the base station 100 to the terminal 200 has been described, the base station 100 and the terminal 200 may adaptively set the SRS subband (RBs constituting the SRS subband) set in the virtual carrier based on the relationship on the frequency axis between the first band and the segment included in the virtual carrier for the terminal 200.

In this manner, according to the present embodiment, the configuration of the SRS subbands is changed according to the continuity on the frequency axis between the first band and the segments that configure the virtual carrier. As a result, according to the continuity of the first band and the segment on the frequency axis, it is possible to simplify the processing while suppressing the influence of the gap on the frequency axis on the channel quality measurement accuracy in the base station 100.

The embodiments of the present disclosure have been described above.

In Embodiments 5 to 12, regarding the RBG, PRG, CSI subband, or SRS subband, when the first band and the segment are discontinuous on the frequency axis, each boundary is aligned with the boundary between the first band and the segment. However, when the first band and the segments are discontinuous on the frequency axis, the RBG, PRG, CSI subbands or SRS subbands may be configured without considering the boundaries between the first band and the segments. In such a case, for example, in a PRG composed of RBs of the first band and segment RBs (for example, PRG#9 in the upper diagram of FIG. 20), different precoding may be applied to RBs within the same PRG (RB#25 and RB#1, #2 in PRG#9 of the upper diagram of FIG. 20). In addition, with regard to CSI subbands and SRS subbands, terminal 200 may drop transmission of CSI subbands (for example, CSI subband #9 in the upper diagram of FIG. 22) and SRS subbands (for example, SRS subband #9 in the upper diagram of FIG. 24 ) composed of RBs of the first band and segment RBs.

The present disclosure can be implemented in software, hardware, or software in conjunction with hardware. Each functional block used in the description of the above embodiments may be partially or wholly implemented as an LSI, which is an integrated circuit, and each process described in the above embodiments may be partially or wholly controlled by one LSI or a combination of LSIs. An LSI may be composed of individual chips, or may be composed of one chip so as to include some or all of the functional blocks. The LSI may have data inputs and outputs. LSIs are also called ICs, system LSIs, super LSIs, and ultra LSIs 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. Also, an FPGA (Field Programmable Gate Array) that can be programmed after the LSI is manufactured, or a reconfigurable processor that can reconfigure the connections and settings of the circuit cells inside the LSI may be used. The present disclosure may be implemented as digital or analog processing. Furthermore, if an integration technology that replaces the LSI appears due to advances in semiconductor technology or another derived technology, the technology may naturally be used to integrate the functional blocks. Application of biotechnology, etc. is possible.

The base station of the present disclosure includes a circuit that determines parameters for a second band composed of the first band and a segment that is an additional band to the first band, and a transceiver that communicates with the terminal in the second band using the parameters.

In the base station of the present disclosure, the parameter is a resource block group (RBG) size configured for the second band, and the circuit determines the RBG size based on the bandwidth of the second band.

In the base station of the present disclosure, the parameter is the resource block group (RBG) size set in the second band, and the circuit determines the RBG size of the second band to be X times the RBG size set based on the bandwidth of the first band (where X is an integer of 2 or more).

In the base station of the present disclosure, the parameter is a resource block group (RBG) size configured in the second band, and the circuit determines a power of 2 as the RBG size.

In the base station of the present disclosure, the RBG size is variable, and the RBG size is notified from the base station to the terminal.

In the base station of the present disclosure, the circuit sets the RBGs such that a boundary between the plurality of RBGs set in the second band and a boundary between the first band and the segment match.

The terminal of the present disclosure includes a circuit that determines parameters for a second band composed of the first band and a segment that is an additional band to the first band, and a transceiver that communicates with a base station in the second band using the parameters.

The communication method of the present disclosure determines parameters for a second band composed of the first band and a segment that is an additional band to the first band, and uses the parameters to communicate with the terminal in the second band.

The communication method of the present disclosure determines parameters for a second band composed of the first band and a segment that is an additional band to the first band, and uses the parameters to communicate with the base station in the second band.

One aspect of the present disclosure is useful for mobile communication systems.

100 base station 101, 208 control unit 102 data generation unit 103, 106, 109, 210 encoding unit 104, 107, 110, 211 modulation unit 105 upper control signal generation unit 108 downlink control signal generation unit 111, 213 signal allocation unit 112, 214 IFFT unit 113, 215 transmission unit 114 , 201 antenna 115, 202 receiving section 116, 203 FFT section 117, 204 extracting section 118 CSI demodulating section 119 SRS measuring section 205 downlink control signal demodulating section 206 higher control signal demodulating section 207 downlink data signal demodulating section 209 CSI generating section 212 SRS generating section

Claims (17)

A circuit that determines the number of resource blocks that make up a resource block group, which is a unit for allocating resources in a first band or a second band having a different bandwidth from the first band to a terminal;
a transceiver that communicates with a base station using the resource;
and
The subcarrier spacing in the first band and the subcarrier spacing in the second band are each set to one of a plurality of subcarrier spacings including 15 kHz, 30 kHz and 60 kHz, and the number of resource blocks determined in the first band and the number of resource blocks determined in the second band are powers of 2.
terminal. The number of resource blocks for the first band is determined based on the bandwidth of the first band, and the number of resource blocks for the second band is determined based on the bandwidth of the second band.
A terminal according to claim 1 . the number of resource blocks for the second band is determined based on the bandwidth of the second band instead of the bandwidth of the first band;
A terminal according to claim 1 or 2. The subcarrier spacing forming the resource blocks in the second band is different from the subcarrier spacing forming the resource blocks in the first band,
A terminal according to any one of claims 1 to 3. The number of subcarriers that make up the resource block is 12 regardless of the subcarrier spacing.
A terminal according to claim 4. The transceiver receives information about the number of resource blocks that make up the resource block group from the base station.
A terminal according to any one of claims 1 to 5. wherein the transceiver receives information about the bandwidth of the first band and information about the bandwidth of the second band from the base station;
A terminal according to any one of claims 1 to 6. The transceiver receives control information from the base station on the first band and data from the base station on the second band.
A terminal according to any one of claims 1 to 7. Determining the number of resource blocks constituting a resource block group, which is a unit for allocating resources in a first band or a second band having a different bandwidth from the first band to a terminal;
using the resource to communicate with a base station;
and
The subcarrier spacing in the first band and the subcarrier spacing in the second band are each set to one of a plurality of subcarrier spacings including 15 kHz, 30 kHz and 60 kHz, and the number of resource blocks determined in the first band and the number of resource blocks determined in the second band are powers of 2.
Communication method. The number of resource blocks for the first band is determined based on the bandwidth of the first band, and the number of resource blocks for the second band is determined based on the bandwidth of the second band.
The communication method according to claim 9. the number of resource blocks for the second band is determined based on the bandwidth of the second band instead of the bandwidth of the first band;
The communication method according to claim 9 or 10. The subcarrier spacing forming the resource blocks in the second band is different from the subcarrier spacing forming the resource blocks in the first band,
A communication method according to any one of claims 9 to 11. The number of subcarriers that make up the resource block is 12 regardless of the subcarrier spacing.
The communication method according to claim 12. receiving information about the number of resource blocks that make up the resource block group from the base station;
A communication method according to any one of claims 9 to 13. receiving information about the bandwidth of the first band and information about the bandwidth of the second band from the base station;
A communication method according to any one of claims 9 to 14. receiving control information from the base station on the first band and receiving data from the base station on the second band;
A communication method according to any one of claims 9 to 15. A process of determining the number of resource blocks constituting a resource block group, which is a unit for allocating resources in a first band or a second band having a different bandwidth from the first band to a terminal;
a process of communicating with a base station using the resource;
to control the
The subcarrier spacing in the first band and the subcarrier spacing in the second band are each set to one of a plurality of subcarrier spacings including 15 kHz, 30 kHz and 60 kHz, and the number of resource blocks determined in the first band and the number of resource blocks determined in the second band are powers of 2.
integrated circuit.

Images