Patent Description:
As a mechanism for supporting a future information society, an M2M (Machine-to-Machine) communication system that achieves services through autonomous communication between devices without asking users to make determinations is expected these years. A smart grid is a specific application of the M2M communication system. The smart grid is an infrastructure system that efficiently supplies a lifeline such as electricity or gas, and performs M2M communication between a smart meter installed in a household or a building and a central server in order to adjust a supply-demand balance of resources autonomously and effectively. Other applications of the M2M communication system include a monitoring system for article management, distance medicine, or the like and remote management of stock or charging of vending machines.

In the M2M communication system, in particular, use of cellular systems having large communication areas is gaining attention. The 3GPP (3rd Generation Partnership Project), which is a standardization group of cellular communication systems, is examining M2M based on a cellular network under a name of Machine Type Communication (MTC) for standardization of LTE (Long Term Evolution) and LTE-Advanced. In particular, further expansion of communication areas is being examined in consideration of cases where MTC communication devices such as smart meters are provided in places such as basements of buildings and are not available in existing communication areas (e.g., refer to NPL <NUM>). In order to further expand the communication areas, for example, repetition, in which the same signals are transmitted a plurality of times, is being examined.

In a cellular communication system, channels used in uplink, which is communication from a terminal to a base station, are a PUCCH (Physical Uplink Control Channel) and a PUSCH (Physical Uplink Shared Channel). The PUCCH is a channel for transmitting a response to a downlink data signal transmitted through a PDSCH (Physical Downlink Shared Channel), such as a positive response (ACK: Acknowledgement) or a negative response (NACK: Negative Acknowledgement) (hereinafter described as an "ACK/NACK"; also referred to as a response signal), and control information such as a Scheduling Request (SR) indicating a request to assign resources. On the other hand, the PUSCH is a channel for transmitting data signals. An ACK/NACK, for example, is <NUM>-bit information indicating either ACK (no error) or NACK (there is an error). PUCCH resources used by the terminal to transmit an ACK/NACK and an SR are secured in advance. In the following description, PUCCH resources used for an ACK/NACK will be referred to as "ACK/NACK resources", and PUCCH resources used for an SR will be referred to as "SR resources".

<CIT> discloses systems and methods for handling of scheduling request collisions with an ACK/NACK repetition signal. A pending scheduling request may be refrained from being transmitted due to the collision. The SR counter may be refrained from incrementing and the SR prohibit timer may be refrained from starting such that additional latency is not introduced into the scheduling request procedure. Alternatively, a pending scheduling request may be transmitted with the ACK/NACK repetition signal in the same subframe when the collision occurs. The ACK/NACK repetition signal may be transmitted on the SR PUCCH resource to indicate a positive scheduling request. If there is no pending scheduling request to be transmitted, the ACK/NACK repetition signal may be transmitted on the ACK/NACK PUCCH resource.

<CIT> discloses a method and an apparatus for allocating to a terminal device multiple terminal device-specific physical uplink control channel resources for a transmission of a scheduling request from the terminal device. The transmission of the scheduling request comprises multiple physical uplink control channel transmissions taking place on the allocated resources. <CIT> discloses systems and methods for signaling and determining transmissions time interval (TTI) bundling parameters. A signaling may be received that indicates a TTI bundling configuration, a signaling may be received that indicates an uplink grant, at least one TTI bundling parameter may be determined based on the TTI bundling configuration and the uplink grant, and a signal based on the at least one TTI bundling parameter may be transmitted.

In Release <NUM> (hereinafter referred to as "Rel. <NUM>") of LTE, if transmission of a PUSCH is not assigned to the same subframe as one in which an ACK/NACK is transmitted, the ACK/NACK is transmitted through the PUCCH. In addition, for example, a signal point of Binary Phase Shift Keying (BPSK) is used for an ACK/NACK, and an ACK is transmitted using a signal point of -<NUM>, and a NACK is transmitted using a signal point of +<NUM>.

<FIG> illustrates an example of transmission of an ACK/NACK and an SR using PUCCH resources in Rel. "Information to be transmitted" illustrated in <FIG> indicates a signal to be transmitted in each subframe, and A/N indicates an ACK/NACK (the same holds in the subsequent drawings).

As illustrated in <FIG>, if an SR is not transmitted in the same subframe as one in which an ACK/NACK is transmitted, the ACK/NACK is transmitted using an ACK/NACK resource. On the other hand, if transmission of an SR occurs in the same subframe as one in which an ACK/NACK is transmitted, the ACK/NACK is transmitted using an SR resource. In addition, in a subframe in which only transmission of an SR occurs, the SR is transmitted using an SR resource. If only an SR is transmitted, the SR is transmitted using a signal point of +<NUM> (the same signal point as a NACK) in BPSK (e.g., refer to NPL <NUM>).

A base station identifies, through blind detection such as a power determination, a resource (an ACK/NACK resource or an SR resource) with which an ACK/NACK is transmitted. If determining that the ACK/NACK has been transmitted using an SR resource, the base station determines that there is an SR and decodes the ACK/NACK using a signal of the SR resource. On the other hand, if determining that the ACK/NACK has been transmitted using an ACK/NACK resource, the base station determines that there is no SR and decodes the ACK/NACK using a signal of the ACK/NACK resource. In addition, if detecting a signal of an SR resource at a timing other than timings (known timings) at which ACK/NACKs are received in response to downlink data signals, the base station determines that there is an SR.

<NUM>, if transmission of a PUSCH is assigned to the same subframe as one in which an ACK/NACK is transmitted, the ACK/NACK is transmitted through the PUSCH.

<FIG> illustrates an example of transmission of a PUSCH and an ACK/NACK in Rel. In "information to be transmitted" illustrated in <FIG>, Data indicates an uplink data signal (hereinafter also referred to simply as data) (the same holds in the subsequent drawings).

As illustrated in <FIG>, in a subframe in which only an ACK/NACK is transmitted, the ACK/NACK is transmitted using an ACK/NACK resource. In addition, in a subframe only data is assigned, the data is transmitted using a PUSCH.

In addition, as illustrated in <FIG>, if data is assigned to the same subframe as one in which an ACK/NACK is transmitted, the ACK/NACK is time-multiplexed with a data signal and transmitted in a PUSCH. More specifically, by puncturing part of a data signal mapped in a resource adjacent to a Reference Signal (RS), the ACK/NACK is arranged in the resource for that part (e.g., refer to NPL <NUM>).

The base station determines whether an ACK/NACK is included in a received PUSCH through blind detection. Here, the base station can detect a timing at which an ACK/NACK is transmitted in response to a downlink data signal (PDSCH) on the basis of assignment of the downlink data signal in a PDCCH (Physical Downlink Control Channel). The base station can therefore decode the PUSCH while assuming that an ACK/NACK is included, without performing blind detection in a subframe in which the terminal must transmit the ACK/NACK. Due to the following reason, however, the base station determines presence or absence of an ACK/NACK through blind detection. If the terminal fails to receive a PDCCH with which the terminal is notified of assignment of a downlink data signal, the terminal does not transmit an ACK/NACK but transmits only a data signal using a PUSCH. At this time, the PUSCH includes only the data signal, but if the base station decodes the PUSCH while assuming that the PUSCH includes an ACK/NACK, data signal decoding properties deteriorate. The base station therefore, initially needs to determine whether an ACK/NACK is included.

<NUM>, ACK/NACK repetition in the PUCCH in which the maximum number of repetitions is six is introduced. <FIG> illustrates an example of ACK/NACK repetition and SR transmission in PUCCH resources in Rel.

An ACK/NACK repetition is transmitted using ACK/NACK resources secured in advance. In addition, as illustrated in <FIG>, if transmission of an SR occurs in the same subframe as one in which transmission of an ACK/NACK repetition, priority is given to the transmission of the ACK/NACK repetition using an ACK/NACK resource, and the SR is dropped (not transmitted) (e.g., refer to NPL <NUM>).

In order to achieve the above-described further expansion of the communication areas, introduction of repetition is closely examined in LTE-Advanced Release <NUM> (hereinafter referred to as "Rel. <NUM>") and later. Although ACK/NACK repetition is specified in Rel. <NUM>, the number of repetitions is desired to be increased in order to further expand the communication areas. In addition, SR repetition and PUSCH repetition, which are not conducted in Rel. <NUM>, are also effective.

Details of a case in which repetition transmission is applied to a plurality of signals such as an ACK/NACK, an SR, and a PUSCH, however, have not yet been examined.

An aspect of the present disclosure, therefore, provides a base station according to independent claim <NUM> and a communication method according to independent claim <NUM> capable of avoiding deterioration of signal reception properties (decoding properties, detection properties, and the like) when repetition transmission is applied to an ACK/NACK and an SR.

Preferred embodiments are provided by the dependent claims. [<NUM>] In the following description, examples directed to transmission of an ACK/NACK and a PUSCH are present for illustration purposes and do not fall within the scope of the claims.

According to an aspect of the present disclosure, deterioration of signal reception properties can be avoided when repetition transmission is applied to an ACK/NACK and an SR.

First, a problem that can arise when repetition transmission is applied to a plurality of signals such as an ACK/NACK, an SR, and a PUSCH will be described.

<FIG> illustrate examples of ACK/NACK repetition transmission and SR repetition transmission in the PUCCH.

If ACK/NACK repetition transmission and SR repetition transmission are performed in the PUCCH, the SR repetition transmission might occur during the ACK/NACK repetition transmission as illustrated in <FIG>.

At this time, in a method (refer to <FIG>) in which priority is given to the ACK/NACK repetition transmission as in Rel. <NUM>, an SR in the same subframe as one in which an ACK/NACK is transmitted is dropped as illustrated in <FIG>, and a necessary number of SRs (four subframes in <FIG>) are not transmitted, thereby deteriorating SR detection properties in a base station.

On the other hand, if transmission of an SR occurs in the same subframe as one in which an ACK/NACK is transmitted, a method may be used in which the ACK/ACK is transmitted using an SR resource (refer to <FIG>). In this method, however, as illustrated in <FIG>, resources used for transmitting ACK/NACKs might change from ACK/NACK resources to SR resources during the ACK/NACK repetition. Furthermore, the base station needs to identify, through blind detection such as a power determination, resources used for transmitting the ACK/NACKs, but in this method, the base station is likely to be unable to determine whether an SR is transmitted until all of repeatedly transmitted SRs are received. As a result, an accuracy of determining resources used for transmitting the ACK/NACKs might deteriorate, thereby deteriorating ACK/NACK decoding properties.

In addition to the case described with reference to <FIG> in which "SR repetition transmission occurs during ACK/NACK repetition transmission", a case in which "ACK/NACK repetition transmission occurs during SR repetition transmission" (not illustrated) is possible. In this case, the base station can decode ACK/NACKs after receiving all of repeatedly transmitted SRs. A signal point of SR resources, however, might change during the SR repetition transmission because signals transmitted using the SR resources change from SRs to ACK/NACKs during the SR repetition transmission. As a result, in-phase combination cannot be performed at a time of detection of the SRs, and the SR detection properties might deteriorate.

<FIG> illustrates an example of ACK/NACK repetition transmission and PUSCH repetition transmission.

If ACK/NACK repetition transmission and PUSCH repetition transmission are performed, the ACK/NACK repetition transmission might occur during the PUSCH repetition transmission as illustrated in <FIG>. At this time, in a subframe in which an ACK/NACK and a PUSCH (data signal) are assigned, a method may be used in which the data signal and the ACK/NACK are time-multiplexed with each other and transmitted in a PUSCH (refer to <FIG>).

In this method, however, a signal in the PUSCH might change from a signal including only data to a signal in which data and an ACK/NACK are time-multiplexed with each other during the PUSCH repetition transmission. The base station needs to determine whether an ACK/NACK is included through blind detection. The base station, however, is likely to be unable to determine whether an ACK/NACK is included in a PUSCH until a signal including data and an ACK/NACK is received the number of repetitions of an ACK/NACK (four subframes in <FIG>).

If content of a signal in a PUSCH changes during the PUSCH repetition transmission, therefore, an accuracy of determining whether an ACK/NACK is included in a PUSCH might deteriorate in het base station, thereby deteriorating the ACK/NACK decoding properties and PUSCH data decoding properties.

In addition to the case described with reference to <FIG> in which "ACK/NACK repetition transmission occurs during PUSCH repetition transmission", a case in which "PUSCH repetition transmission occurs during ACK/NACK repetition transmission" is possible. In this case, too, the same problem as above arises.

On the basis of the above knowledge, embodiments of the present disclosure will be described in detail hereinafter with reference to the drawings. In the embodiments, the same components are given the same reference numerals.

In the following description, an FDD (Frequency Division Duplex) system will be taken as an example.

In addition, a communication system according to each embodiment of the present disclosure is a system according to LTE-Advanced, for example, and includes a base station <NUM> and a terminal <NUM>.

When transmitting an ACK/NACK, an SR, and a PUSCH, the terminal <NUM> applies repetition transmission to at least two of the ACK/NACK, the SR, and the PUSCH. When performing the repetition transmission, the terminal <NUM> repeatedly transmits each signal in consecutive subframes corresponding to a certain number of repetitions (Repetition Factor).

<FIG> is a block diagram illustrating essential components of the base station <NUM> according to each embodiment of the present disclosure. In the base station <NUM> illustrated in <FIG>, a setting unit <NUM> generates control information (timing information) for identifying a first subframe (start position) at which repetition transmission of an uplink signal (an SR or an uplink data signal) starts and a second subframe (start position) at which repetition transmission of a response signal (ACK/NACK) for a downlink data signal starts. A reception unit <NUM> receives, from the terminal <NUM> to which the control information has been transmitted, an uplink signal repeatedly transmitted using a certain number of consecutive subframes starting with the first subframe and a response signal repeatedly transmitted using at least the certain number of consecutive subframes starting with the second subframe. It is to be noted that the first subframe (start position) of the repetition transmission of the uplink signal (the SR or the uplink data signal) is set to be the same as the second subframe (start position) for the ACK/NACK repetition transmission. The "setting subframes (start positions) to be the same" refers to setting the same subframes (time resources) (the start positions are temporally identical). In addition, if a plurality of first subframes and a plurality of second subframes are set, the "setting subframes (start positions) to be the same" refers to setting each of the plurality of first subframes to be the same as one of the plurality of second subframes.

<FIG> is a block diagram illustrating essential components of the terminal <NUM> according to each embodiment of the present disclosure. In the terminal <NUM> illustrated in <FIG>, a setting information reception unit <NUM> receives information indicating a first subframe (start position) at which repetition transmission of an uplink signal (an SR or an uplink data signal) starts and a second subframe (start position) at which repetition transmission of a response signal (ACK/NACK) for a downlink data signal starts. A transmission unit <NUM> repeatedly transmits the uplink signal using a certain number of consecutive subframes starting with the first subframe and the response signal using at least the certain number of consecutive subframes starting with the second subframe.

<FIG> is a block diagram illustrating the configuration of the base station <NUM> according to a first embodiment of the present disclosure. In <FIG>, the base station <NUM> includes the setting unit <NUM>, a coding unit <NUM>, a modulation unit <NUM>, a control information generation unit <NUM>, a signal assignment unit <NUM>, an OFDM (Orthogonal Frequency Division Multiplexing) signal generation unit <NUM>, a transmission unit <NUM>, an antenna <NUM>, the reception unit <NUM>, an FFT (Fast Fourier Transform) unit <NUM>, a PUSCH demodulation unit <NUM>, a PUCCH extraction unit <NUM>, a PUCCH demodulation unit <NUM>, and an ACK/NACK decoding unit <NUM>.

The setting unit <NUM> generates timing information regarding subframes (hereinafter referred to as start positions) at which repetition transmission of at least two of an ACK/NACK, an SR, and a PUSCH starts in the terminal <NUM>. The timing information may be assigned to a PDCCH and transmitted to the terminal <NUM>, or may be transmitted to the terminal <NUM> in a semi-static manner as a higher layer control signal (RRC: Radio Resource Control). If the timing information is assigned to a PDCCH and transmitted to the terminal <NUM>, the setting unit <NUM> outputs the timing information to the control information generation unit <NUM>. If the timing information is transmitted as a higher layer control signal, the setting unit <NUM> outputs the timing information to the coding unit <NUM>. Details of a method for setting start positions of repetition transmission used by the setting unit <NUM> will be described later.

The coding unit <NUM> performs error correction coding, such as turbo coding, on transmission data (a bit sequence, that is, a downlink data signal) and outputs a resultant coded bit sequence to the modulation unit <NUM>.

The modulation unit <NUM> performs a data modulation process on the coded bit sequence received from the coding unit <NUM> and outputs a resultant data modulation signal to the signal assignment unit <NUM>.

The control information generation unit <NUM> generates control information to be assigned to a PDCCH, performs a coding and modulation process on the control information, and outputs a resultant control information modulation signal to the signal assignment unit <NUM>.

The signal assignment unit <NUM> maps a data modulation signal received from the modulation unit <NUM> in a downlink data signal assignment resource and outputs the mapped signal to the OFDM signal generation unit <NUM>. In addition, the signal assignment unit <NUM> maps the control signal modulation signal received from the control information generation unit <NUM> in a downlink control information assignment resource and outputs the mapped signal to the OFDM signal generation unit <NUM>.

The OFDM signal generation unit <NUM> performs subcarrier mapping and an IFFT (Inverse Fast Fourier Transform) process on the signals received from the signal assignment unit <NUM> to generate a time-domain OFDM signal. The OFDM signal generation unit <NUM> outputs the generated OFDM signal to the transmission unit <NUM>.

The transmission unit <NUM> performs an RF (Radio Frequency) process such as D/A (Digital-to-Analog) conversion or up-conversion on the OFDM signal received from the OFDM signal generation unit <NUM> and transmits a radio signal to the terminal <NUM> through the antenna <NUM>.

The reception unit <NUM> performs an RF process such as down-conversion or A/D (Analog-to-Digital) conversion on a radio signal received from the terminal <NUM> through the antenna <NUM> and outputs a resultant baseband DFT-S-OFDM (Discrete Fourier Transform-spread-Orthogonal Frequency Division Multiplexing) signal to the FFT unit <NUM>. The received DFT-S-OFDM signal includes an ACK/NACK, an SR, or a PUSCH subjected to repetition transmission.

The FFT unit <NUM> converts the DFT-S-OFDM signal received from the reception unit <NUM> into a frequency-domain signal by performing an FFT process. The FFT unit <NUM> outputs the resultant frequency-domain signal to the PUSCH demodulation unit <NUM> and the PUCCH extraction unit <NUM>.

The PUSCH demodulation unit <NUM> extracts a PUSCH from the signal received from the FFT unit <NUM> and demodulates the extracted PUSCH. More specifically, the PUSCH demodulation unit <NUM> determines whether the PUSCH includes an ACK/NACK through a blind determination. If determining that an ACK/NACK is not included, the PUSCH demodulation unit <NUM> demodulates a data signal and performs an error correction process such as turbo coding and an error detection process such as a CRC determination to obtain reception data. On the other hand, if determining that an ACK/NACK is included, the PUSCH demodulation unit <NUM> separates a data signal and the ACK/NACK from each other, outputs the ACK/NACK signal to the ACK/NACK decoding unit <NUM>, and performs the above processes on the data signal to obtain reception data.

The PUCCH extraction unit <NUM> extracts a PUCCH from the signal received from the FFT unit <NUM> and outputs the extracted PUCCH to the PUCCH demodulation unit <NUM>.

The PUCCH demodulation unit <NUM> demodulates the PUCCH received from the PUCCH extraction unit <NUM>. More specifically, the PUCCH demodulation unit <NUM> identifies, through blind detection such as a power determination, a resource (an ACK/NACK resource or an SR resource) used for transmitting the ACK/NACK. If determining that the ACK/NACK has been transmitted using an SR resource, the PUCCH demodulation unit <NUM> determines that there is an SR and outputs the ACK/ACK to the ACK/NACK decoding unit <NUM>. In addition, if determining that the ACK/NACK has been transmitted using an ACK/NACK resource, the PUCCH demodulation unit <NUM> determines that there is no SR and outputs the ACK/NACK to the ACK/NACK decoding unit <NUM>. In addition, if determining that only an SR has been transmitted using an SR resource, the PUCCH demodulation unit <NUM> determines that there is an SR.

The ACK/NACK decoding unit <NUM> performs a decoding process on the ACK/NACK received from the PUSCH demodulation unit <NUM> or the PUCCH demodulation unit <NUM> to obtain a reception ACK/NACK (an ACK or a NACK). The obtained reception ACK/NACK is used by a retransmission control unit (not illustrated) to determine whether to retransmit a corresponding downlink data signal or transmit new data.

<FIG> is a block diagram illustrating the configuration of the terminal <NUM> according to the first embodiment of the present disclosure. In <FIG>, the terminal <NUM> includes an antenna <NUM>, a reception unit <NUM>, a demodulation unit <NUM>, a decoding unit <NUM>, a coding unit <NUM>, a modulation unit <NUM>, an ACK/NACK generation unit <NUM>, an SR generation unit <NUM>, the setting information reception unit <NUM>, a control channel formation unit <NUM>, an ACK/NACK multiplexing unit <NUM>, a DFT-S-OFDM signal generation unit <NUM>, and the transmission unit <NUM>.

The reception unit <NUM> performs an RF process such as down-conversion or AD conversion on a radio signal received from the base station <NUM> through the antenna <NUM> to obtain a baseband OFDM signal. The reception unit <NUM> outputs the OFDM signal to the demodulation unit <NUM>. In addition, the reception unit <NUM> outputs a PDCCH including timing information for identifying start positions of a plurality of consecutive subframes used for repetition transmission of at least two of an ACK/NACK, an SR, and a PUSCH in the OFDM signal or a higher layer control signal to the setting information reception unit <NUM>.

The demodulation unit <NUM> performs a demodulation process on the OFDM signal received from the reception unit <NUM>, extracts data (downlink data signal), and outputs the data to the decoding unit <NUM>.

The decoding unit <NUM> performs an error correction process such as turbo decoding and an error detection process such as a CRC (Cyclic Redundancy Check) determination on the data received from the demodulation unit <NUM>. The decoding unit <NUM> outputs an obtained result of the error detection to the ACK/NACK generation unit <NUM>.

The coding unit <NUM> performs error correction coding such as turbo coding on transmission data (a bit sequence, that is, an uplink data signal) and outputs a resultant coded bit sequence to the modulation unit <NUM>.

The modulation unit <NUM> performs a data modulation process on the coded bit sequence received from the coding unit <NUM> and outputs a resultant data modulation signal to the ACK/NACK multiplexing unit <NUM>.

The ACK/NACK generation unit <NUM> generates an ACK/NACK on the basis of the result of the error detection received from the decoding unit <NUM>. More specifically, if an error is detected, the ACK/NACK generation unit <NUM> generates an ACK, and if an error is not detected, the ACK/NACK generation unit <NUM> generates a NACK. The ACK/NACK generation unit <NUM> outputs the generated ACK/NACK to the control channel formation unit <NUM>.

If a scheduling request to the base station <NUM> occurs, the SR generation unit <NUM> generates an SR signal and outputs the SR signal to the control channel formation unit <NUM>.

The setting information reception unit <NUM> reads the timing information received from the reception unit <NUM>. The setting information reception unit <NUM> then sets, in accordance with read transmission timings, subframes (start positions) at which repetition transmission of at least two of an ACK/NACK, an SR, and a PUSCH starts and outputs the subframes to the control channel formation unit <NUM> and the ACK/NACK multiplexing unit <NUM>.

The control channel formation unit <NUM> secures certain PUCCH transmission resources and identifies in advance the timings (subframes that are candidates for start positions) of repetition transmission of an ACK/NACK and an SR received from the setting information reception unit <NUM>. The control channel formation unit <NUM> forms a PUCCH for transmitting control information including an ACK/NACK and/or an SR using a certain format in accordance with the timings of repetition transmission of an ACK/NACK and an SR received from the setting information reception unit <NUM> depending on cases such as independent transmission of an ACK/NACK, independent transmission of an SR, and simultaneous transmission of an ACK/NACK and an SR. In addition, if transmission of an ACK/NACK and transmission of a PUSCH (uplink data signal) occur in the same subframe, the control channel formation unit <NUM> outputs the ACK/NACK to the ACK/NACK multiplexing unit <NUM> without including the ACK/NACK in a PUCCH. The control channel formation unit <NUM> outputs the formed PUCCH to the DFT-S-OFDM signal generation unit <NUM>.

The ACK/NACK multiplexing unit <NUM> identifies in advance the timings (subframes that are candidates for start positions) of repetition transmission of an ACK/NACK and a PUSCH received from the setting information reception unit <NUM>. The ACK/NACK multiplexing unit <NUM> forms a PUSCH on the basis of a certain format in accordance with the timings of repetition transmission of an ACK/NACK and a PUSCH received from the setting information reception unit <NUM> depending on cases such as independent transmission of data and simultaneous transmission of an ACK/NACK and data. The ACK/NACK multiplexing unit <NUM> outputs the formed PUSCH to the DFT-S-OFDM signal generation unit <NUM>.

The DFT-S-OFDM signal generation unit <NUM> performs a DFT process, subcarrier mapping, and an IFFT process on the PUCCH received from the control channel formation unit <NUM> or the PUSCH received from the ACK/NACK multiplexing unit <NUM> to generate a time-domain DFT-S-OFDM signal. The DFT-S-OFDM signal generation unit <NUM> outputs the generated DFT-S-OFDM signal to the transmission unit <NUM>.

The transmission unit <NUM> performs an RF process such as D/A conversion or up-conversion on the DFT-S-OFDM signal received from the DFT-S-OFDM signal generation unit <NUM> and transmits a radio signal to the base station <NUM> through the antenna <NUM>. In doing so, at least two of an ACK/NACK, an SR, and a PUSCH are repeatedly transmitted using a plurality of consecutive subframes starting from a start position of the repetition transmission read by the setting information reception unit <NUM>.

The operation of the base station <NUM> and the terminal <NUM> having the above configurations will be described. It is to be noted that ACK/NACK repetition transmission and SR repetition transmission through the PUCCH will be described hereinafter.

In the following description, the number of repetitions of an ACK/NACK and the number of repetitions of an SR are the same.

The base station <NUM> sets, for the terminal <NUM>, subframes (candidates for start positions) at which the ACK/NACK repetition transmission starts and subframes (candidates for start positions) at which the SR repetition transmission starts. More specifically, the base station <NUM> matches the start positions of the SR repetition transmission with the start positions of the ACK/NACK repetition transmission. That is, the base station <NUM> sets each of the start positions of the SR repetition transmission to the same subframe for one of the start positions of the ACK/NACK repetition transmission. It is to be noted that the base station <NUM> may set the start positions of the SR repetition transmission to the same subframes for all the start positions of the ACK/NACK repetition transmission.

The base station <NUM> (setting unit <NUM>) then transmits timing information for identifying the set start positions of the ACK/NACK repetition transmission and the set start positions of the SR repetition transmission to the terminal <NUM>, for example, through higher layer signaling.

For example, the base station <NUM> performs assignment (e.g., DL assignment) of a downlink data signal corresponding to an ACK/NACK. The terminal <NUM> can identify a subframe a certain number of subframes after a subframe in which the assignment of the downlink data signal has been received as a transmission timing of the ACK/NACK for the downlink data signal. As the timing information, therefore, existing control information indicating the assignment of the downlink data signal may be used, instead. In this case, the terminal <NUM> may identify the start positions of the ACK/NACK repetition transmission on the basis of the timing information (the assignment of the downlink data signal: the existing control information) and set part or all of the start positions of the ACK/NACK repetition transmission as the start positions of the SR repetition transmission. The signaling for setting the start positions of the SR repetition transmission, therefore, becomes unnecessary.

Alternatively, the base station <NUM> may set the start positions of the SR repetition transmission and transmit timing information indicating the setting to the terminal <NUM>. In this case, the terminal <NUM> may set the transmitted start positions of the SR repetition transmission as the start positions of the ACK/NACK repetition transmission. Alternatively, the base station <NUM> may set arbitrary subframes as the start positions of the ACK/NACK and SR repetition transmission and transmit timing information indicating the setting to the terminal <NUM>.

The terminal <NUM> (setting information reception unit <NUM>) receives the timing information transmitted from the base station <NUM> and sets the start positions (subframes) of the ACK/NACK and SR repetition transmission. The terminal <NUM> (transmission unit <NUM>) then repeatedly transmits an ACK/NACK using consecutive subframes, which correspond to a certain number of repetitions, starting with a subframe that is a start position of the ACK/NACK repetition transmission and an SR using consecutive subframes, which correspond to a certain number of repetitions, starting with a subframe that is a start position of the SR repetition transmission.

<FIG> illustrates an example of transmission timings of ACK/NACKs and SRs. It is to be noted that in <FIG>, the number of repetitions of an ACK/NACK and an SR is four (four subframes) each.

As illustrated in <FIG>, in a subframe in which only an ACK/NACK is transmitted, the terminal <NUM> transmits the ACK/NACK using an ACK/NACK resource. In addition, in a subframe in which only an SR is transmitted, the terminal <NUM> transmits the SR using an SR resource.

In addition, as illustrated in <FIG>, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, the terminal <NUM> transmits ACK/NACKs using SR resources.

Here, the terminal <NUM> (setting information reception unit <NUM>) sets each of start positions of the SR repetition transmission to the same subframe for one of start positions of the ACK/NACK repetition transmission. That is, as illustrated in <FIG>, the start positions of the SR repetition transmission are at least the same as the start positions of the ACK/NACK repetition transmission.

In addition, as illustrated in <FIG>, the number of repetitions of an ACK/NACK and an SR is the same, namely four subframes.

If ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, therefore, subframes used for the ACK/NACK repetition transmission and subframes used for the SR repetition transmission are the same. That is, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, the terminal <NUM> transmits ACK/NACKs using SR resources in all subframes in a period of the ACK/NACK and SR repetition transmission. In other words, in consecutive subframes (four consecutive subframes in <FIG>) in a period of the SR repetition transmission, resources used for transmitting the ACK/NACKs do not switch in midstream as in <FIG>.

As described above, according to the present embodiment, since the resources for transmitting the ACK/NACKs do not change in the period of the SR repetition transmission as in <FIG>, the base station <NUM> can decode the ACK/NACKs after receiving all of repeatedly transmitted SRs and determining whether the SRs have been transmitted. As a result, deterioration of the ACK/NACK decoding properties can be avoided.

Furthermore, according to the present embodiment, since the resources used for transmitting the ACK/NACKs do not change in the period of the SR repetition transmission, a signal point of the SR resources does not change during the SR repetition transmission. In-phase combination can therefore be performed at a time of detection of the SRs, thereby improving the SR detection properties.

In addition, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, the terminal <NUM> transmits ACK/NACKs using SR resources in all subframes in a period of the SR repetition transmission. As a result, according to the present embodiment, an SR need not be dropped if an ACK/NACK and the SR occur in the same subframe as in <FIG>, thereby avoiding deterioration of SR detection properties.

In addition, according to the present embodiment, a case in which "ACK/NACK repetition transmission occurs during SR repetition transmission" does not occur, and, as in the above case, deterioration of the SR detection properties due to lack of in-phase combination at the time of the detection of SRs can be avoided.

In the first embodiment, the ACK/NACK repetition transmission and the SR repetition transmission through the PUCCH have been described. In the present embodiment, ACK/NACK repetition transmission and PUSCH repetition transmission through the PUSCH will be described.

It is to be noted that basic configurations of a base station and a terminal according to the present embodiment are the same as those according to the first embodiment and will be described with reference to <FIG> (base station <NUM>) and <FIG> (terminal <NUM>).

In the following description, as in the first embodiment, the number of repetitions of an ACK/NACK and the number of repetitions of a PUSCH are the same.

The base station <NUM> sets, for the terminal <NUM>, subframes (candidates for start positions) at which the ACK/NACK repetition transmission starts and subframes (candidates for start positions) at which the PUSCH repetition transmission starts. The base station <NUM>, for example, sets the start positions of the ACK/NACK repetition transmission to the same subframes for the start positions of the PUSCH repetition transmission. Alternatively, the base station <NUM> may set each of the start positions of the ACK/NACK repetition transmission to one of the start positions of the PUSCH repetition transmission, or may set each of the start positions of the PUSCH repetition transmission to one of the start positions of the ACK/NACK repetition transmission.

The base station <NUM> (setting unit <NUM>) then transmits timing information for identifying the set start positions of the ACK/NACK repetition transmission and the set start positions of the PUSCH repetition transmission to the terminal <NUM>, for example, through higher layer signaling.

For example, the base station <NUM> performs assignment (UL grant) of an uplink data signal using a downlink control channel (PDCCH) to the terminal <NUM>. That is, the terminal <NUM> can identify a transmission timing of the uplink data signal on the basis of the assignment of the uplink data signal. As the timing information, therefore, existing control information indicating the assignment of the uplink data signal may be used, instead. In this case, the terminal <NUM> (setting information reception unit <NUM>) may identify the start positions of the PUSCH repetition transmission on the basis of the timing information (the assignment of the uplink data signal: the existing control information) and set part or all of the start positions of the PUSCH repetition transmission as the start positions of the ACK/NACK repetition transmission. The signaling for setting the start positions of the ACK/NACK repetition transmission, therefore, becomes unnecessary.

Alternatively, the base station <NUM> may set arbitrary subframes as the start positions of the PUSCH and ACK/NACK repetition transmission and transmit timing information indicating the setting to the terminal <NUM>.

The terminal <NUM> (setting information reception unit <NUM>) sets the start positions (subframes) of the ACK/NACK and PUSCH repetition transmission on the basis of the timing information transmitted from the base station <NUM>. The terminal <NUM> (transmission unit <NUM>) then repeatedly transmits an ACK/NACK using consecutive subframes, which correspond to a certain number of repetitions, starting with a subframe that is a start position of the ACK/NACK repetition transmission and a PUSCH using consecutive subframes, which correspond to a certain number of repetitions, starting with a subframe that is a start position of the PUSCH repetition transmission.

<FIG> illustrates an example of transmission timings of ACK/NACKs and PUSCHs. It is to be noted that in <FIG>, the number of repetitions of an ACK/NACK and a PUSCH is four (four subframes) each.

As illustrated in <FIG>, in a subframe in which only an ACK/NACK is transmitted, the terminal <NUM> transmits the ACK/NACK using an ACK/NACK resource. In addition, in a subframe in which only data is transmitted, the terminal <NUM> transmits the data using a PUSCH.

In addition, as illustrated in <FIG>, if ACK/NACK repetition transmission and PUSCH repetition transmission occur in the same subframes, the terminal <NUM> time-multiplexes and transmits ACK/NACKs and data in the PUSCH.

Here, the terminal <NUM> (setting information reception unit <NUM>) sets start positions of the ACK/NACK repetition transmission to the same subframe for start positions of the PUSCH repetition transmission. That is, as illustrated in <FIG>, the start positions of the ACK/NACK repetition transmission are the same as the start positions of the PUSCH repetition transmission.

In addition, as illustrated in <FIG>, the number of repetitions of an ACK/NACK and a PUSCH is the same, namely four subframes.

If ACK/NACK repetition transmission and PUSCH repetition transmission occur in the same subframes, therefore, subframes used for repeatedly transmitting the ACK/NACK and subframes used for repeatedly transmitting the PUSCH are the same. That is, if ACK/NACK repetition transmission and PUSCH repetition transmission occur in the same subframes, the terminal <NUM> time-multiplexes and transmits the ACK/NACKs and the data using PUSCHs in all subframes in a period of the ACK/NACK and data repetition transmission. In other words, in consecutive subframes (four consecutive subframes in <FIG>) in a period of the PUSCH repetition transmission, resources used for transmitting the ACK/NACKs do not switch or a signal in a PUSCH in the period of the ACK/NACK repetition transmission does not change as in <FIG>.

As described above, according to the present embodiment, since the signal repeatedly transmitted in the PUSCH does not change in the period of the ACK/NACK repetition transmission as in <FIG>, the base station <NUM> can determine whether ACK/NACKs are included in PUSCHs after receiving a PUSCH repetition including data and an ACK/NACK the number of times of ACK/NACK repetitions. As a result, deterioration of the ACK/NACK decoding properties is likely to be avoided.

In addition, according to the present embodiment, a case in which "PUSCH repetition transmission occurs during ACK/NACK repetition transmission" does not occur, and, as in the above case, deterioration of the ACK/NACK decoding properties is likely to be avoided.

In the present embodiment, a case will be described in which start positions of ACK/NACK repetition transmission and SR repetition transmission in the PUCCH are periodically set.

In the following description, as in the first embodiment, the number of repetitions of an ACK/NACK and the number of repetitions of a SR are the same.

The base station <NUM> and the terminal <NUM> periodically set the start positions (subframes) of the ACK/NACK repetition transmission and the start positions (subframes) of the SR repetition transmission. The base station <NUM> and the terminal <NUM>, for example, set a period of the start positions of the SR repetition transmission to an integral multiple of a period of the start positions of the ACK/NACK repetition transmission. Alternatively, the period of the start positions of the SR repetition transmission and the period of the start positions of the ACK/NACK repetition transmission may be the same.

In addition, as in the first embodiment, the base station <NUM> and the terminal <NUM> match the start positions (subframes) of the SR repetition transmission with the start positions of the ACK/NACK repetition transmission. In addition, as in the first embodiment, if the ACK/NACK and SR transmission is in the same subframes, the terminal <NUM> transmits ACK/NACKs using SR resources.

<FIG> illustrates an example of transmission timings of ACK/NACKs and SRs according to the present embodiment.

In <FIG>, the number of repetitions of an ACK/NACK and an SR is four each.

In addition, as illustrated in <FIG>, the period of the start positions of the ACK/NACK repetition transmission is four subframes (that is, <NUM>), and the period of the start positions of the SR repetition transmission is eight subframes (that is, <NUM>). That is, the period of the start positions of the SR repetition transmission is twice (an integral multiple of) the period of the start positions of the ACK/NACK repetition transmission.

In addition, as illustrated in <FIG>, the start positions (subframes) of the SR repetition transmission are matched with the start positions of the ACK/NACK repetition transmission as in the first embodiment. That is, each of the subframes that are the start positions of the SR repetition transmission is the same as one of the subframes that are the start positions of the ACK/NACK repetition transmission. In addition, as illustrated in <FIG>, if the ACK/NACK and SR transmission is in the same subframes, ACK/NACKs are transmitted using SR resources as in the first embodiment.

The above-described start positions of the ACK/NACK repetition transmission are represented as subframes that satisfy the following expression. <NUM>] <MAT>.

In Expression (<NUM>), nf denotes a system frame number, ns denotes a slot number in a frame, and NACK/NACK denotes the number of ACK/NACK repetitions in the PUCCH. NACK/NACK is transmitted from the base station <NUM> to the terminal <NUM> in advance, for example, as timing information. That is, the terminal <NUM> (setting information reception unit <NUM>) sets the start positions of the ACK/NACK repetition transmission in accordance with Expression (<NUM>) using the timing information transmitted from the base station <NUM>.

On the other hand, the above-described start positions of the SR repetition transmission are represented as subframes that satisfy the following expression. <NUM>] <MAT>.

SRPERIODICITYenhanced and NOFFSET,SRenhanced in Expression (<NUM>), however, are given in accordance with the following expression. <NUM>] <MAT>.

In Expression (<NUM>), NSR denotes the number of SR repetitions, and NACK/NACK = NSR in the present embodiment. In addition, SRPERIODICITY and NOFFSET,SR are defined by a table illustrated in <FIG> and calculated by a parameter ISR transmitted from the base station <NUM> to the terminal <NUM>. That is, the terminal <NUM> (setting information reception unit <NUM>) sets the start positions of the SR repetition transmission in accordance with the table illustrated in <FIG> and Expressions (<NUM>) and (<NUM>) using ISR and NACK/NACK (= NSR) indicated in the timing information transmitted from the base station <NUM>.

<FIG>, for example, illustrates an example in which the base station <NUM> transmits NACK/NCK = NSR = <NUM> and ISR = <NUM> to the terminal <NUM>. That is, since NSR = NACK/NCK and, as illustrated in <FIG>, SRPERIODICITY is an integer, SRPERIODICITYenhanced (= SRPERIODICITYNSR) in Expression (<NUM>), which denotes the period of the start positions of the SR repetition transmission, is an integral multiple of NACK/NCK, which denotes the period of the start positions of the ACK/NACK repetition transmission.

In the present embodiment, if there is an ACK/NACK to be transmitted in a subframe that is a start position of the ACK/NACK repetition transmission, the terminal <NUM> transmits the ACK/NACK using NACK/NCK consecutive subframes starting with the subframe that is the start position of the ACK/NACK repetition transmission. In addition, if there is an SR to be transmitted in a subframe that is a start position of the SR repetition transmission, the terminal <NUM> transmits the SR using NSR consecutive subframes starting with the subframe that is the start position of the SR repetition transmission.

At this time, as in the first embodiment, the terminal <NUM> transmits ACK/NACKs using ACK/NACK resources in subframes in which ACK/NACK repetitions are independently transmitted. In addition, the terminal <NUM> transmits SRs using SR resources in subframes in which SR repetitions are independently transmitted. On the other hand, the terminal <NUM> transmits ACK/NACKs using SR resources in subframes in which SR repetitions and ACK/NACK repetitions are simultaneously transmitted.

In doing so, as in the first embodiment, the start positions of the SR repetition transmission are matched with the start positions of the ACK/NACK repetition transmission. That is, the SR repetition transmission does not occur during the ACK/NACK repetition transmission, or the ACK/NACK repetition transmission does not occur in the period of the SR repetition transmission. Resources used for transmitting ACK/NACKs therefore do not change during the SR repetition transmission. The base station <NUM> can thus decode the ACK/NACKs after receiving all of repeatedly transmitted SRs and determining whether the SRs have been transmitted. As a result, deterioration of the ACK/NACK decoding properties can be avoided.

Furthermore, as in the first embodiment, since the resources used for transmitting the ACK/NACKs do not change in the period of the SR repetition transmission, a signal point of the SR resources does not change during the SR repetition transmission. In-phase combination can therefore be performed at a time of detection of the SRs, thereby improving the SR detection properties.

In addition, as in the first embodiment, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, the terminal <NUM> transmits ACK/NACKs using SR resources in all subframes in a period of the SR repetition transmission. As a result, an SR need not be dropped if an ACK/NACK and the SR occur in the same subframe as in <FIG>, thereby avoiding deterioration of the SR detection properties.

In addition, as in the first embodiment, a case in which "ACK/NACK repetition transmission occurs during SR repetition transmission" does not occur, and, as in the above case, deterioration of the SR detection properties due to lack of in-phase combination at the detection of SRs can be avoided.

Furthermore, in the present embodiment, since the start positions of the ACK/NACK repetition transmission are set to predetermined periodical subframes, the system can be easily controlled in terms of the ACK/NACK repetition transmission.

In addition, in the present embodiment, since the period of the start positions of the SR repetition transmission is set to an integral multiple of the period of the start positions of the ACK/NACK repetition transmission, the base station <NUM> can easily notify the terminal <NUM> of the start positions (subframes and a period) of the repetition transmission. In the present embodiment, for example, the terminal <NUM> can identify the period NSR (= NACK/NCK) of the start positions of the SR repetition transmission on the basis of the period NACK/NCK of the start positions of the ACK/NACK repetition transmission. In addition, the terminal <NUM> can calculate (Expressions (<NUM>) and (<NUM>)) the start positions of the repetition transmission using the existing correspondence table (<FIG>) just by receiving NACK/NCK (= NSR) and ISR from the base station <NUM>.

In the present embodiment, as in the third embodiment, a case will be described in which start positions of ACK/NACK repetition transmission and start positions of PUSCH repetition transmission in the PUSCH are periodically set.

In the following description, as in the second embodiment, the number of repetitions of an ACK/NACK and the number of repetitions of a PUSCH are the same.

The base station <NUM> and the terminal <NUM> periodically set the start positions (subframes) of the ACK/NACK repetition transmission and the start positions (subframes) of the PUSCH repetition transmission. The base station <NUM> and the terminal <NUM>, for example, set a period of the start positions of the ACK/NACK repetition transmission to be the same as a period of the start positions of the PUSCH repetition transmission. Alternatively, either of the period of the start positions of the ACK/NACK repetition transmission and the period of the start positions of the PUSCH repetition transmission may be an integral multiple of the other.

In addition, as in the second embodiment, the base station <NUM> and the terminal <NUM> match the start positions (subframes) of the ACK/NACK repetition transmission with the start positions of the PUSCH repetition transmission. In addition, as in the second embodiment, if the ACK/NACK and PUSCH transmission is in the same subframes, the terminal <NUM> time-multiplexes and transmits ACK/NACKs and PUSCHs in the PUSCH.

<FIG> illustrates an example of transmission timings of ACK/NACKs and PUSCHs according to the present embodiment.

In <FIG>, the number of repetitions of an ACK/NACK and a PUSCH is four each.

In addition, as illustrated in <FIG>, the period of the start positions of the PUSCH repetition transmission is four subframes (that is, <NUM>), and the period of the start positions of the ACK/NACK repetition transmission, too, is four subframes (that is, <NUM>). That is, the period of the start positions of the ACK/NACK repetition transmission is the same as the period of the start positions of the PUSCH repetition transmission.

In addition, as illustrated in <FIG>, the start positions (subframes) of the ACK/NACK repetition transmission are matched with the start positions of the PUSCH repetition transmission as in the second embodiment. That is, the subframes that are the start positions of the ACK/NACK repetition transmission are the same as the subframes that are the start positions of the PUSCH repetition transmission. In addition, as illustrated in <FIG>, if the ACK/NACK and PUSCH transmission is in the same subframes, ACK/NACKs and PUSCHs are time-multiplexed and transmitted in the PUSCH as in the second embodiment. A method for multiplexing data and ACK/NACKs in the same subframes of the PUSCH is the same as a conventional one.

On the other hand, the above-described start positions of the PUSCH repetition transmission are represented as subframes that satisfy the following expression. <NUM>] <MAT>.

In Expression (<NUM>), NPUSCH denotes the number of PUSCH repetitions, and NPUSCH = NACK/NACK in the present embodiment. That is, the terminal <NUM> (setting information reception unit <NUM>) can set the start positions of the PUSCH repetition transmission in accordance with Expression (<NUM>) using the timing information (NACK/NACK (= NPUSCH)) regarding the ACK/NACK repetition transmission transmitted from the base station <NUM>.

<FIG>, for example, illustrates an example in which the base station <NUM> transmits NPUSCH = NACK/NACK = <NUM> to the terminal <NUM>.

In the present embodiment, if there is an ACK/NACK to be transmitted in a subframe that is a start position of the ACK/NACK repetition transmission, the terminal <NUM> transmits the ACK/NACK using NACK/NCK consecutive subframes starting with the subframe that is the start position of the ACK/NACK repetition transmission. In addition, if there is data to be transmitted in a subframe that is a start position of the PUSCH repetition transmission, the terminal <NUM> transmits the data using NPUSCH consecutive subframes starting with the subframe that is the start position of the PUSCH repetition transmission.

At this time, as in the second embodiment, the terminal <NUM> transmits ACK/NACKs using ACK/NACK resources in subframes in which ACK/NACK repetitions are independently transmitted. In addition, the terminal <NUM> transmits data using PUSCHs in subframes in which PUSCH repetitions are independently transmitted. On the other hand, the terminal <NUM> time-multiplexes and transmits ACK/NACKs and data in the PUSCH in subframes in which PUSCH repetitions and ACK/NACK repetitions are simultaneously transmitted.

In doing so, as in the second embodiment, the ACK/NACK repetition transmission does not occur during the PUSCH repetition transmission, and a signal in the PUSCH does not change in a period of the PUSCH repetition transmission. The base station <NUM> can therefore determine whether ACK/NACKs are included in PUSCHs after receiving a PUSCH repetition including data and an ACK/NACKs the number of times of ACK/NACK repetitions. As a result, deterioration of the ACK/NACK decoding properties is likely to be avoided.

Furthermore, in the present embodiment, since the start positions of the ACK/NACK repetition transmission and the PUSCH repetition transmission are set to predetermined periodical subframes, the system can be easily controlled in terms of the ACK/NACK repetition transmission and the PUSCH repetition transmission.

In addition, in the present embodiment, since the period of the start positions of the ACK/NACK repetition transmission is set to be the same as the period of the start positions of the PUSCH repetition transmission, the base station <NUM> can easily notify the terminal <NUM> of the start positions (subframes and a period) of the repetition transmission. In the present embodiment, for example, the terminal <NUM> can identify the period NACK/NACK (= NPUSCH) of the start positions of the ACK/NACK repetition transmission on the basis of the period NPUSCH of the start positions of the PUSCH repetition transmission.

In the first and third embodiments, cases in which the number of repetitions of an ACK/NACK and the number of repetitions of an SR in the PUCCH are the same have been described. The number of repetitions of an ACK/NACK and the number of repetitions of an SR in the PUCCH, however, are not necessarily the same. In the present embodiment, therefore, a case will be described in which the number of repetitions of an ACK/NACK and the number of repetitions of an SR in the PUCCH are different from each other.

In <FIG>, the number of repetitions of an ACK/NACK is four subframes, and the number of repetitions of an SR is eight subframes. That is, the number of repetitions of an SR is larger than the number of repetitions of an ACK/NACK.

As illustrated in <FIG>, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, ACK/NACKs are transmitted using SR resources in subframes (first four subframes) in which the ACK/NACKs and SRs are transmitted, and SRs are transmitted using SR resources in other subframes (last four subframes) after completion of the ACK/NACK repetition transmission. That is, if the number of repetitions of an SR is larger than the number of repetitions of an ACK/NACK, a signal point of the SR resources might undesirably change in midstream in a period of the SR repetition transmission (eight subframes). If the signal point of the SR resources changes in midstream, in-phase combination cannot be performed at a time of detection of SRs, thereby deteriorating the SR detection properties.

In the present embodiment, therefore, a method will be described by which deterioration of the SR detection properties can be avoided even if the number of repetitions of an ACK/NACK and the number of repetitions of an SR in the PUCCH are different from each other, in addition to the operations according to the first embodiment.

More specifically, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, the terminal <NUM> according to the present embodiment sets the number of repetitions of an ACK/NACK in the PUCCH to the number of repetitions of an SR or the number of repetitions of an ACK/NACK, whichever is larger.

In the example illustrated in <FIG>, for example, the number of repetitions of an ACK/NACK is four subframes, and the number of repetitions of an SR is eight subframes. That is, the predetermined number of SR repetitions (eight subframes) is larger than the predetermined number of ACK/NACK repetitions (four subframes). In this case, as illustrated in <FIG>, if ACK/NACK repetition transmission and SR repetition transmission occur in the same subframes, the terminal <NUM> repeatedly transmits an ACK/NACK the same number of times (eight subframes) as the SR repetition transmission. That is, the number of repetitions of an ACK/NACK is set to the larger number (eight subframes) between the number of repetitions of an SR (eight subframes) and the number of repetitions of an ACK/NACK (four subframes).

In doing so, if ACK/NACK repetition transmission and SR repetition transmission simultaneously occur, ACK/NACKs are transmitted using SR resources in all subframes in a period of the SR repetition transmission. Since a signal point of the SR resources does not change in the period of the SR repetition transmission, the base station <NUM> can detect SRs through in-phase combination, and it is likely that deterioration of the SR detection properties can be avoided.

In addition, in <FIG>, if ACK/NACK repetition transmission and SR repetition transmission simultaneously occur, the number of repetitions of an ACK/NACK is increased and becomes the same as the number of repetitions of an SR, and the ACK/NACK decoding properties in the base station <NUM> can be improved.

It is to be noted that in <FIG>, a case in which the number of repetitions of an ACK/NACK is smaller than the number of repetitions of an SR has been described. On the other hand, if the predetermined number of repetitions of an ACK/NACK is larger than the predetermined number of repetitions of an SR, the terminal <NUM> uses the predetermined number of repetitions of an ACK/NACK. In doing so, even if ACK/NACK repetition transmission and SR repetition transmission simultaneously occur, ACK/NACKs are transmitted using SR resources at least in a period of the SR repetition transmission. A signal point of the SR resources therefore does not change in midstream, thereby avoiding deterioration of the SR detection properties. On the other hand, a resource used for transmitting an ACK/NACK in a period of the ACK/NACK repetition transmission switches from an SR resource to an ACK/NACK resource. Even if the resource used for transmitting an ACK/NACK changes halfway through the ACK/NACK repetition transmission, however, the base station <NUM> can decode the ACK/NACKs without deteriorating the ACK/NACK decoding properties using the ACK/NACKs transmitted using the SR resources in the period of the SR repetition transmission and the ACK/NACKs transmitted using the ACK/NACK resources in periods other than the period of the SR repetition transmission.

In the second and fourth embodiments, cases in which the number of repetitions of an ACK/NACK and the number of repetitions of a PUSCH (data) in the PUSCH are the same have been described. The number of repetitions of an ACK/NACK and the number of repetitions of data in the PUSCH, however, are not necessarily the same. In the present embodiment, therefore, as in the fifth embodiment, a case will be described in which the number of repetitions of an ACK/NACK and the number of repetitions of data in the PUSCH are different from each other.

In <FIG>, the number of repetitions of an ACK/NACK is four subframes, and the number of repetitions of a PUSCH (data) is eight subframes. That is, the number of repetitions of a PUSCH is larger than the number of repetitions of an ACK/NACK.

As illustrated in <FIG>, if ACK/NACK repetition transmission and PUSCH repetition transmission occur in the same subframes, ACK/NACKs and data are time-multiplexed and transmitted in the PUSCH in subframes (first four subframes) in which the ACK/NACKs and the data are transmitted, and only data is transmitted in the PUSCH in other subframes (last four subframes) after completion of the ACK/NACK repetition transmission. That is, if the number of repetitions of a PUSCH is larger than the number of repetitions of an ACK/NACK, data content in the PUSCH might undesirably change in a period of the PUSCH repetition transmission (eight subframes). If the data content in the PUSCH changes in midstream, data decoding properties deteriorate, and the ACK/NACK decoding properties also deteriorate.

In the present embodiment, therefore, a method will be described by which deterioration of the data decoding properties and the ACK/NACK decoding properties can be avoided even if the number of repetitions of an ACK/NACK and the number of repetitions of data in the PUSCH are different from each other, in addition to the operations according to the second embodiment.

More specifically, if ACK/NACK repetition transmission and PUSCH repetition transmission occur in the same subframes, the terminal <NUM> according to the present embodiment sets the number of repetitions of an ACK/NACK in the PUSCH to the number of repetitions of a PUSCH or the number of repetitions of an ACK/NACK, whichever is larger.

In the example illustrated in <FIG>, for example, the number of repetitions of an ACK/NACK is four subframes, and the number of repetitions of data is eight subframes. That is, the predetermined number of PUSCH repetitions (eight subframes) is larger than the predetermined number of ACK/NACK repetitions (four subframes). In this case, as illustrated in <FIG>, if ACK/NACK repetition transmission and PUSCH repetition transmission occur in the same subframes, the terminal <NUM> repeatedly transmits an ACK/NACK the same number of times (eight subframes) as the PUSCH repetition transmission. That is, the number of repetitions of an ACK/NACK is set to the larger number (eight subframes) between the number of repetitions of a PUSCH (eight subframes) and the number of repetitions of an ACK/NACK (four subframes).

In doing so, if ACK/NACK repetition transmission and PUSCH repetition transmission simultaneously occur, ACK/NACKs and data are time-multiplexed and transmitted in the PUSCH in all subframes in a period of the PUSCH repetition transmission. Since data content in the PUSCH does not change in the period of the PUSCH repetition transmission, the base station <NUM> is likely to avoid deterioration of PUSCH data decoding properties. The base station <NUM> is therefore also likely to avoid deterioration of the ACK/NACK decoding properties.

In addition, in <FIG>, if ACK/NACK repetition transmission and PUSCH repetition transmission simultaneously occur, the number of repetitions of an ACK/NACK is increased and becomes the same as the number of repetitions of a PUSCH, and the ACK/NACK decoding properties in the base station <NUM> can be improved.

It is to be noted that in <FIG>, a case in which the number of repetitions of an ACK/NACK is smaller than the number of repetitions of data has been described. On the other hand, if the predetermined number of repetitions of an ACK/NACK is larger than the predetermined number of repetitions of data, the terminal <NUM> uses the predetermined number of repetitions of an ACK/NACK. In doing so, even if ACK/NACK repetition transmission and PUSCH repetition transmission simultaneously occur, ACK/NACKs and data are time-multiplexed transmitted in the PUSCH at least in a period of the PUSCH repetition transmission. Data content in the PUSCH therefore does not change in midstream, thereby avoiding deterioration of the data detection properties and the ACK/NACK decoding properties. On the other hand, a resource used for transmitting an ACK/NACK in a period of the ACK/NACK repetition transmission switches from a PUSCH to an ACK/NACK resource in the PUCCH. Even if the resource used for transmitting ACK/NACKs changes halfway through the ACK/NACK repetition transmission, however, the base station <NUM> can decode the ACK/NACKs without deteriorating the ACK/NACK decoding properties using the ACK/NACKs transmitted in the PUSCH in the period of the PUSCH repetition transmission and the ACK/NACKs transmitted using the ACK/NACK resources in periods other than the period of the PUSCH repetition transmission.

The embodiments of the present disclosure have been described.

It is to be noted that although cases in which the present disclosure is configured by hardware have been taken as examples in the embodiments, the present disclosure can be implemented by software that cooperates with hardware.

In addition, function blocks used to describe the embodiments are achieved as LSI, which is typically an integrated circuit. These may be separately achieved as chips, or some or all of these may be achieved as a chip. Although LSI has been mentioned here, a term IC, system LSI, super LSI, or ultra LSI might be used, instead, depending on a difference in a degree of integration.

In addition, a method for obtaining an integrated circuit is not limited to LSI, but an integrated circuit may be achieved as a dedicated circuit or a general-purpose processor. An FPGA (field-programmable gate array) for which programming can be performed after an LSI is fabricated or a reconfigurable processor capable of reconfiguring connections and settings of circuit cells inside an LSI may be used, instead.

Furthermore, if a technique for obtaining an integrated circuit that replaces LSI appears as a result of evolution of semiconductor technologies or from a different derivative technique, the function blocks may be achieved as integrated circuits using the technique. Application of a biological technology is a possibility.

A terminal in the present disclosure includes a reception unit that receives information indicating a first subframe at which repetition transmission of an uplink signal starts and a second subframe at which repetition transmission of a response signal for a downlink data signal starts, and a transmission unit that repeatedly transmits the uplink signal using a certain number of consecutive subframes starting with the first subframe and the response signal using at least the certain number of consecutive subframes starting with the second subframes. The first subframe is set to be the same as the second subframe.

In the terminal in the present disclosure, the first subframe and the second subframe are periodically set.

In the terminal in the present disclosure, a period of the first subframe is set to an integral multiple of a period of the second subframe.

In the terminal in the present disclosure, a period of the first subframe and a period of the second subframe are the same.

In the terminal in the present disclosure, a number of repetitions predetermined for the response signal and a number of repetitions predetermined for the uplink signal are the same.

In the terminal in the present disclosure, if a first number of repetitions predetermined for the response signal and a second number of repetitions predetermined for the uplink signal are different from each other and the repetition transmission of the response signal and the repetition transmission of the uplink signal occur in the same subframes, the number of repetitions of the response signal is set to the first number of repetitions or the second number of repetitions, whichever is larger.

In the terminal in the present disclosure, the uplink signal is a scheduling request to a base station from the terminal. If the repetition transmission of the response signal and the repetition transmission of the scheduling request occur in the same subframes, the transmission unit transmits the response signal using a resource for the scheduling request.

In the terminal in the present disclosure, the uplink signal is an uplink data signal. If the repetition transmission of the response signal and the repetition transmission of the uplink data signal occur in the same subframes, the transmission unit time-multiplexes and transmits the response signal and the uplink data signal in an uplink data channel.

A base station in the present disclosure includes a setting unit that generates control information for identifying a first subframe at which repetition transmission of an uplink signal starts and a second subframe at which repetition transmission of a response signal for a downlink data signal starts, and a reception unit that receives, from a terminal that has received the control information, the uplink signal repeatedly transmitted using a certain number of consecutive subframes starting with the first subframe and the response signal repeatedly transmitted using at least the certain number of consecutive subframes starting with the second subframe. The setting unit sets the first subframe to be the same as the second subframe.

A transmission method in the present disclosure includes a reception step of receiving information indicating a first subframe at which repetition transmission of an uplink signal starts and a second subframe at which repetition transmission of a response signal for a downlink data signal starts, and a transmission step of repeatedly transmitting the uplink signal using a certain number of consecutive subframes starting with the first subframe and the response signal using at least the certain number of consecutive subframes starting with the second subframe. The first subframe is set to be the same as the second subframe.

A reception method in the present disclosure includes a setting step of generating control information for identifying a first subframe at which repetition transmission of an uplink signal starts and a second subframe at which repetition transmission of a response signal for a downlink data signal starts, and a reception step of receiving, from a terminal that has received the control information, the uplink signal repeatedly transmitted using a certain number of consecutive subframes starting with the first subframe and the response signal repeatedly transmitted using at least the certain number of consecutive subframes starting with the second subframe. In the setting step, the first subframe is set to be the same as the second subframe.

Disclosures in the specification, drawings, and abstract included in <CIT> are all used to assist the present application.

Claim 1:
A base station comprising:
a transmission unit which, in operation, transmits information indicating a first subframe at which repetition transmission of a Scheduling Request, SR, starts and a second subframe at which repetition transmission of an Acknowledgement/Negative Acknowledgement, ACK/NACK, for a downlink data signal starts; and
a reception unit which, in operation, repeatedly receives the SR using a first certain number of consecutive subframes starting at the first subframe and the ACK/NACK using at least the first certain number of consecutive subframes starting at the second subframe,
wherein a subframe in a defined number of subframes after a subframe in which the information has been transmitted is identified as the second subframe, and the second subframe is set as the first subframe, and
wherein a number of repetitions predetermined for the ACK/NACK and a number of repetitions predetermined for the SR are the same.