JP5863738B2 - Terminal device, base station device, communication method, and integrated circuit - Google Patents

Description

The present invention is a terminal apparatus, base station apparatus, relates to a communication method and integrated circuits.

  3GPP (Third Generation Partnership Project) in due LTE (Long Term Evolution), in the LTE-A (LTE-Advanced) and wireless communication systems, such as the IEEE WiMAX due to the (The Institute of Electrical and Electronics engineers) (Worldwide Interoperability for Microwave Access) is Each of the base station and the terminal is provided with one or a plurality of transmission / reception antennas, and high-speed data transmission can be realized by using, for example, a MIMO (Multiple Input Multiple Output) technique.

  Here, in a wireless communication system, it is considered that a plurality of terminals support MU-MIMO (Multiple User MIMO) that performs spatial multiplexing using the same frequency and time resources. In addition, it has been studied to support a CoMP (Cooperative Multipoint) transmission scheme in which a plurality of base stations cooperate with each other to perform interference coordination. For example, a wireless communication system in a heterogeneous network deployment (HetNet; Heterogeneous Network deployment) such as a macro base station with a wide coverage and an RRH (Remote Radio Head) with a narrower coverage than the macro base station is being studied.

  In such a wireless communication system, when uplink signals (uplink data and uplink control information) transmitted by each of a plurality of terminals have the same characteristics, interference occurs. In addition, when uplink reference signals transmitted by each of a plurality of terminals have the same characteristics, interference occurs. Here, for example, a method for orthogonalizing a demodulation reference signal in order to reduce and suppress interference of a demodulation reference signal (DMRS; also referred to as a Demodulation Reference Signal) transmitted by each of a plurality of terminals Has been proposed (Non-Patent Document 1).

DMRS enhancements for UL CoMP; 3GPP TSG RAN WG1 meeting # 68 R1-120277, February 6th-10th, 2012.

  However, in the wireless communication system as described above, there is no description regarding a specific procedure when the base station and the terminal determine parameters relating to the uplink signal or the uplink reference signal. That is, there is no description of how the base station and the terminal determine parameters related to the uplink signal or the uplink reference signal and perform communication.

The present invention has been made in view of the above problems, and an object of the present invention is to determine a parameter related to an uplink signal or an uplink reference signal so that a base station and a terminal can communicate efficiently . the base station apparatus location, to provide a communication method and an integrated circuit.

  (1) In order to achieve the above object, the present invention takes the following measures. That is, when the physical downlink control channel is detected in the common search space and is a mobile station device that communicates with the base station device, it is related to the transmission of the physical uplink channel generated using the first parameter. And when the physical downlink control channel is detected in the user equipment specific search space, the physical uplink channel generated using the second parameter is transmitted. A reference signal for demodulation related to transmission is transmitted to the base station apparatus.

  (2) In addition, when the physical downlink control channel is arranged in the common search space, the physical uplink channel generated using the first parameter is a base station device that communicates with the mobile station device. When receiving a demodulation reference signal related to transmission of the mobile station apparatus from the mobile station apparatus and arranging the physical downlink control channel in a user apparatus specific search space, the second reference parameter is generated using the second parameter, A demodulation reference signal related to transmission of a physical uplink channel is received from the mobile station apparatus.

  (3) In addition, in the communication method of the mobile station apparatus that communicates with the base station apparatus, when the physical downlink control channel is detected in the common search space, the physical uplink generated using the first parameter When a demodulation reference signal related to transmission of a link channel is transmitted to the base station device, and the physical downlink control channel is detected in a user device specific search space, the second reference parameter is used to generate the reference signal. A demodulation reference signal related to transmission of the physical uplink channel is transmitted to the base station apparatus.

  (4) In addition, in the communication method of the base station apparatus that communicates with the mobile station apparatus, when the physical downlink control channel is arranged in the common search space, the physical method generated using the first parameter When a demodulation reference signal related to transmission of an uplink channel is received from the mobile station apparatus and the physical downlink control channel is arranged in a user apparatus specific search space, it is generated using the second parameter. In addition, a demodulation reference signal related to transmission of the physical uplink channel is received from the mobile station apparatus.

  (5) In addition, when the physical downlink control channel is detected in the common search space in the integrated circuit mounted on the mobile station device communicating with the base station device, it is generated using the first parameter. A function of transmitting a demodulation reference signal related to transmission of a physical uplink channel to the base station apparatus, and a second parameter is used when the physical downlink control channel is detected in a user apparatus specific search space And a function of transmitting the demodulated reference signal related to transmission of the physical uplink channel generated to the base station apparatus, to the mobile station apparatus.

  (6) Further, in an integrated circuit mounted on a base station device that communicates with a mobile station device, when a physical downlink control channel is arranged in a common search space, it is generated using the first parameter. In addition, when the demodulation reference signal related to transmission of the physical uplink channel is received from the mobile station apparatus, and the physical downlink control channel is arranged in the user apparatus specific search space, the second parameter is set to The base station apparatus is caused to exhibit a function of receiving, from the mobile station apparatus, a demodulation reference signal related to transmission of the physical uplink channel generated by use.

  (7) A radio communication system in which a base station device and a mobile station device communicate with each other, wherein the base station device places a physical downlink control channel in a common search space or a user device specific search space, and moves the mobile The station apparatus, when detecting the physical downlink control channel in the common search space, generates a demodulation reference signal related to transmission of the physical uplink channel, generated using the first parameter, in the base station A reference signal for demodulation related to transmission of the physical uplink channel generated using the second parameter when the physical downlink control channel is detected in the user equipment specific search space. Is transmitted to the base station apparatus.

  According to the present invention, a base station and a terminal can determine parameters related to an uplink signal or an uplink reference signal and efficiently communicate with each other.

It is a schematic block diagram which shows the structure of the base station which concerns on embodiment of this invention. It is a schematic block diagram which shows the structure of the terminal which concerns on embodiment of this invention. It is the schematic which shows the example of the communication which concerns on embodiment of this invention. It is a figure which shows the example of a downlink signal. It is a figure explaining embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described. The wireless communication system in the embodiment of the present invention is a base station device (hereinafter also referred to as a base station, a transmission device, a cell, a serving cell, a transmission station, a transmission point, a transmission antenna group, a transmission antenna port group, and an eNodeB). Primary base station (also called macro base station, first base station, first communication device, serving base station, anchor base station, primary cell) and secondary base station (RRH, pico base station, femto base station, Home eNodeB, second base station apparatus, second communication apparatus, cooperative base station group, cooperative base station set, cooperative base station, and secondary cell). Also referred to as a mobile station apparatus (hereinafter referred to as a terminal, a terminal apparatus, a mobile terminal, a receiving apparatus, a receiving point, a receiving terminal, a third communication apparatus, a receiving antenna group, a receiving antenna port group, and a user apparatus (UE)) Provided).

  Here, the secondary base station may be indicated as a plurality of secondary base stations. For example, the primary base station and the secondary base station use a heterogeneous network arrangement, and part or all of the coverage of the secondary base station is included in the coverage of the primary base station, and communication is performed with the terminal.

  FIG. 1 is a schematic block diagram showing the configuration of a base station according to the embodiment of the present invention. Here, the base station shown in FIG. 1 includes a primary base station and a secondary base station. The base station includes a data control unit 101, a transmission data modulation unit 102, a radio unit 103, a scheduling unit 104, a channel estimation unit 105, a reception data demodulation unit 106, a data extraction unit 107, an upper layer 108, And the antenna 109. Radio section 103, scheduling section 104, channel estimation section 105, reception data demodulation section 106, data extraction section 107, upper layer 108 and antenna 109 constitute a reception section. Further, the data control unit 101, the transmission data modulation unit 102, the radio unit 103, the scheduling unit 104, the upper layer 108, and the antenna 109 constitute a transmission unit. Here, each part which comprises a base station is also called a unit.

  The data control unit 101 receives a transport channel from the scheduling unit 104. The data control unit 101 maps signals generated in the transport channel and the physical layer to the physical channel based on scheduling information input from the scheduling unit 104. Each mapped data is output to transmission data modulation section 102.

  The transmission data modulation unit 102 modulates / encodes transmission data. The transmission data modulation unit 102 modulates / encodes the data input from the data control unit 101 based on scheduling information from the scheduling unit 104, serial / parallel conversion of the input signal, IFFT (Inverse Fast Fourier Transform). Conversion: Performs signal processing such as inverse phase Fourier transform (CP) processing and CP (cyclic prefix) insertion, generates transmission data, and outputs the transmission data to the radio section 103.

  Radio section 103 up-converts the transmission data input from transmission data modulation section 102 to a radio frequency to generate a radio signal, and transmits the radio signal to a terminal via antenna 109. Radio section 103 receives a radio signal received from the terminal via antenna 109, down-converts it to a baseband signal, and outputs received data to channel estimation section 105 and received data demodulation section 106.

  The scheduling unit 104 performs mapping between logical channels and transport channels, downlink and uplink scheduling, and the like. Since the scheduling unit 104 controls the processing units of each physical layer in an integrated manner, the scheduling unit 104, the antenna 109, the radio unit 103, the channel estimation unit 105, the reception data demodulation unit 106, the data control unit 101, the transmission data modulation An interface between the unit 102 and the data extraction unit 107 exists.

  In downlink scheduling, the scheduling unit 104 generates transmission control and scheduling information in the transport channel and physical channel based on uplink control information received from the terminal, scheduling information input from the higher layer 108, and the like. To do. The scheduling information used for downlink scheduling is output to the data control unit 101.

  Further, in uplink scheduling, scheduling section 104 generates scheduling information based on the uplink channel state output from channel estimation section 105, scheduling information input from higher layer 108, and the like. Scheduling information used for uplink scheduling is output to the data control unit 101.

  In addition, the scheduling unit 104 maps the downlink logical channel input from the higher layer 108 to the transport channel, and outputs it to the data control unit 101. Also, the scheduling unit 104 processes the uplink transport channel and control data input from the data extraction unit 107 as necessary, maps them to the uplink logical channel, and outputs them to the upper layer 108.

  The channel estimation unit 105 estimates an uplink channel state from an uplink reference signal (for example, a demodulation reference signal) and outputs the uplink channel state to the reception data demodulation unit 106 in order to demodulate the uplink data. Further, in order to perform uplink scheduling, an uplink channel state is estimated from an uplink reference signal (for example, a sounding reference signal) and output to scheduling section 104.

  Received data demodulation section 106 demodulates received data. Based on the uplink channel state estimation result input from the channel estimation unit 105, the reception data demodulation unit 106 performs DFT conversion, subcarrier mapping, IFFT conversion, etc. on the modulation data input from the radio unit 103. Signal processing is performed, demodulation processing is performed, and the data is output to the data extraction unit 107.

  The data extraction unit 107 confirms whether the received data input from the received data demodulation unit 106 is correct and outputs a confirmation result (eg, ACK or NACK) to the scheduling unit 104. The data extraction unit 107 separates the data input from the reception data demodulation unit 106 into a transport channel and physical layer control data, and outputs the data to the scheduling unit 104.

  The upper layer 108 performs processing of a radio resource control (RRC) layer and processing of a MAC (Media Access Control) layer. The upper layer 108 integrates and controls the processing units of the lower layer, so the upper layer 108, the scheduling unit 104, the antenna 109, the radio unit 103, the channel estimation unit 105, the received data demodulation unit 106, the data control unit 101, There is an interface between the transmission data modulation unit 102 and the data extraction unit 107.

  FIG. 2 is a schematic block diagram showing the configuration of the terminal according to the embodiment of the present invention. The terminal includes a data control unit 201, a transmission data modulation unit 202, a radio unit 203, a scheduling unit 204, a channel estimation unit 205, a reception data demodulation unit 206, a data extraction unit 207, an upper layer 208, an antenna 209. The data control unit 201, transmission data modulation unit 202, radio unit 203, scheduling unit 204, upper layer 208, and antenna 209 constitute a transmission unit. The radio unit 203, scheduling unit 204, channel estimation unit 205, reception data demodulation unit 206, data extraction unit 207, higher layer 208, and antenna 209 constitute a reception unit. Here, each part which comprises a terminal is also called a unit.

  The data control unit 201 receives a transport channel from the scheduling unit 204. Further, the data control unit 201 maps signals generated in the transport channel and the physical layer to the physical channel based on the scheduling information input from the scheduling unit 204. Each mapped data is output to transmission data modulation section 202.

  The transmission data modulation unit 202 modulates / encodes transmission data. Transmission data modulation section 202 performs signal processing such as modulation / coding, input signal serial / parallel conversion, IFFT processing, CP insertion on the data input from data control section 201 to generate transmission data. To the wireless unit 203.

  Radio section 203 up-converts transmission data input from transmission data modulation section 202 to a radio frequency, generates a radio signal, and transmits the radio signal to a base station via antenna 209. Radio section 203 receives a radio signal received from the base station via antenna 209, down-converts it to a baseband signal, and outputs the received data to channel estimation section 205 and received data demodulation section 206. .

  The scheduling unit 104 performs mapping between logical channels and transport channels, downlink and uplink scheduling, and the like. Since the scheduling unit 204 controls the processing units of each physical layer in an integrated manner, the scheduling unit 204, the antenna 209, the data control unit 201, the transmission data modulation unit 202, the channel estimation unit 205, the reception data demodulation unit 206, the data There is an interface between the extraction unit 207 and the wireless unit 203.

  In the downlink scheduling, the scheduling unit 204 performs reception control and scheduling information on the transport channel and the physical channel based on downlink control information received from the base station, scheduling information input from the higher layer 208, and the like. Generate. The scheduling information used for downlink scheduling is output to the data control unit 201.

  In addition, in the uplink scheduling, the scheduling unit 204 determines the uplink logical channel input from the upper layer 208 based on the downlink control information received from the base station, the scheduling information input from the upper layer 208, and the like. Scheduling processing for mapping to the transport channel and generation of scheduling information used for uplink scheduling are performed. The scheduling information is output to the data control unit 201.

  Also, the scheduling unit 204 maps the uplink logical channel input from the higher layer 208 to the transport channel, and outputs it to the data control unit 201. The scheduling unit 204 also includes channel state information input from the channel estimation unit 205 and CRC (Cyclic Redundancy Check) parity bits (also simply referred to as CRC) input from the data extraction unit 207. The confirmation result is also output to the data control unit 201.

  In addition, the scheduling unit 204 determines parameters related to the uplink signal, and generates an uplink signal using the determined parameter. In addition, the scheduling unit 204 determines a parameter related to the reference signal, and generates a reference signal using the determined parameter.

  The channel estimation unit 205 estimates a downlink channel state from a downlink reference signal (for example, a demodulation reference signal) for demodulation of downlink data, and outputs the channel state to the reception data demodulation unit 206. Received data demodulation section 206 demodulates the received data input from radio section 203 and outputs the demodulated data to data extraction section 207.

  The data extraction unit 207 confirms the correctness of the reception data input from the reception data demodulation unit 206 and outputs a confirmation result (for example, ACK or NACK) to the scheduling unit 204. Further, the data extraction unit 207 separates the reception data input from the reception data demodulation unit 206 into transport channel and physical layer control data, and outputs the data to the scheduling unit 204.

  The upper layer 208 performs processing of the radio resource control layer and processing of the MAC layer. The upper layer 208 integrates and controls the processing units of the lower layer, so that the upper layer 208, the scheduling unit 204, the antenna 209, the data control unit 201, the transmission data modulation unit 202, the channel estimation unit 205, the reception data demodulation unit 206, an interface between the data extraction unit 207 and the wireless unit 203 exists.

  FIG. 3 is a schematic diagram illustrating an example of communication according to the embodiment of the present invention. In FIG. 3, terminal 303 communicates with primary base station 301 and / or secondary base station 302. In addition, the terminal 304 communicates with the primary base station 301 and / or the secondary base station 302.

  In FIG. 3, when transmitting an uplink signal to a base station, the terminal multiplexes and transmits a demodulation reference signal (DMRS) that is a known signal between the base station and the terminal. . Here, the uplink signal includes uplink data (uplink shared channel (UL-SCH; Uplink Shared Channel), uplink transport block). In addition, uplink control information (UCI) is included in the uplink signal. Here, UL-SCH is a transport channel.

  For example, uplink data is mapped to a physical uplink shared channel (PUSCH). Moreover, uplink control information is mapped by PUSCH or a physical uplink control channel (PUCCH; Physical Uplink Control Channel). That is, in the wireless communication system, a demodulation reference signal related to PUSCH transmission (transmission on PUSCH) is supported. In addition, in a wireless communication system, a demodulation reference signal related to PUCCH transmission (transmission on PUCCH) is supported.

  In the present embodiment, a demodulation reference signal related to PUSCH transmission is also referred to as a first reference signal. In addition, a demodulation reference signal related to PUCCH transmission is also referred to as a second reference signal. The first reference signal and the second reference signal are also referred to as reference signals.

  That is, the first reference signal is used for PUSCH demodulation. For example, the first reference signal is transmitted in a resource block (also referred to as a physical resource block, a physical resource, or a resource) to which the corresponding PUSCH is mapped. The second reference signal is used for demodulation of PUCCH. For example, the second reference signal is transmitted in a resource block to which a corresponding PUCCH is mapped.

  That is, the terminal 303 multiplexes the reference signal with the uplink signal to be transmitted to the primary base station 301 and transmits it through the uplink 305. Further, the terminal 303 multiplexes the reference signal with the uplink signal to be transmitted to the secondary base station 302 and transmits the multiplexed signal through the uplink 306. Further, the terminal 304 multiplexes the reference signal with the uplink signal to be transmitted to the primary base station 301 and transmits the multiplexed signal through the uplink 307. Further, the terminal 304 multiplexes the reference signal with the uplink signal to be transmitted to the secondary base station 302 and transmits the multiplexed signal through the uplink 308.

  Here, when the uplink signal transmitted by the terminal 303 and the uplink signal transmitted by the terminal 304 have the same characteristics, interference occurs. Further, when the reference signal transmitted by the terminal 303 and the reference signal transmitted by the terminal 304 have the same characteristics, interference occurs. For example, when interference occurs in the reference signal transmitted by each of a plurality of terminals, the estimation accuracy of the transmission path state used for demodulating the uplink signal is greatly degraded.

  Therefore, it is desirable to orthogonalize the reference signal transmitted by the terminal 303 and the reference signal transmitted by the terminal 304. Further, it is desirable to orthogonalize the uplink signal transmitted by the terminal 303 and the uplink signal transmitted by the terminal 304. Also, it is desirable to randomize the interference between the reference signal transmitted by the terminal 303 and the reference signal transmitted by the terminal 304. Also, it is desirable to randomize the interference between the uplink signal transmitted by the terminal 303 and the uplink signal transmitted by the terminal 304.

  Here, in FIG. 3, different cell identities (also referred to as Cell IDs) can be set for the primary base station 301 and the secondary base station 302 (also referred to as Different cell IDs). Further, the same cell cell identity can be set for all or a part of the primary base station 101 and the secondary base station 102 (also referred to as Shared cell ID and Same cell ID). Here, the cell identity is also referred to as a physical layer cell identity (physical layer cell identity).

  In FIG. 3, aggregation of a plurality of serving cells (also simply referred to as cells) is supported in the downlink and uplink (referred to as carrier aggregation or cell aggregation). For example, in each serving cell, a transmission bandwidth of up to 110 resource blocks can be used. Here, in the carrier aggregation, one serving cell is defined as a primary cell (Pcell). In carrier aggregation, a serving cell other than the primary cell is defined as a secondary cell (Scell; Secondary Cell).

  Also, a carrier corresponding to a serving cell in the downlink is defined as a downlink component carrier (DLCC; Downlink Component Carrier). Also, a carrier corresponding to a primary cell in the downlink is defined as a downlink primary component carrier (DLPCC; Downlink Primary Component Carrier). A carrier corresponding to a secondary cell in the downlink is defined as a downlink secondary component carrier (DLSCC).

  Furthermore, a carrier corresponding to a serving cell in the uplink is defined as an uplink component carrier (ULCC). Further, a carrier corresponding to a primary cell in the uplink is defined as an uplink primary component carrier (ULPCC; Uplink Primary Component Carrier). Also, a carrier corresponding to a secondary cell in the uplink is defined as an uplink secondary component carrier (ULSCCC).

  That is, in carrier aggregation, a plurality of component carriers are aggregated to support a wide transmission bandwidth. Here, for example, the primary base station 101 can be regarded as a primary cell, and the secondary base station 102 can be regarded as a secondary cell (the base station sets the terminal) (also referred to as HetNet deployment with a carrier aggregation).

  FIG. 4 is a diagram illustrating an example of a downlink signal. FIG. 4 shows a resource area of a physical downlink shared channel (PDSCH; Physical Downlink Shared Channel) to which downlink data (downlink shared channel (DL-SCH; Downlink Shared Channel), downlink transport block) is mapped. It is shown. Here, DL-SCH is a transport channel.

  Moreover, the resource area | region of the physical downlink control channel (PDCCH; Physical Downlink Control PDCCH) where downlink control information (DCI; Downlink Control Information) is mapped is shown. Moreover, the resource area | region of E-PDCCH (Enhanced-PDCCH) to which downlink control information is mapped is shown.

  For example, the PDCCH is mapped to the first to third OFDM symbols in the downlink resource region. The E-PDCCH is mapped to the 4th to 12th OFDM symbols in the downlink resource region. Further, the E-PDCCH is mapped to the first slot and the second slot in one subframe. Further, PDSCH and E-PDCCH are subjected to FDM (Frequency Division Multiplexing). In the present embodiment, E-PDCCH is included in PDCCH.

  Here, the PDCCH is used to notify (designate) downlink control information to the terminal. A plurality of formats are defined for downlink control information transmitted on the PDCCH. Here, the format of the downlink control information is also referred to as a DCI format.

  For example, DCI format 1 and DCI format 1A used for scheduling one PDSCH (one PDSCH codeword, one downlink transport block transmission) in one cell are defined as DCI formats for the downlink. The Also, as a DCI format for the downlink, DCI format 2 used for scheduling of one PDSCH (up to two PDSCH codewords, transmission of up to two downlink transport blocks) in one cell is defined. The

  For example, the DCI format for the downlink includes downlink control information such as information on PDSCH resource allocation and information on MCS (Modulation and Coding scheme). Also, the DCI format for the downlink may include information on a reference sequence index (also referred to as a reference sequence identifier). Also, the DCI format for the downlink may include information on a reference sequence index (also referred to as a reference sequence identifier) related to PUCCH. Hereinafter, the DCI format used for PDSCH scheduling is also referred to as downlink assignment.

  Further, for example, as a DCI format for uplink, DCI format 0 used for scheduling of one PUSCH (one PUSCH codeword, one uplink transport block transmission) in one cell is defined. Also, as a DCI format for uplink, DCI format 4 used for scheduling of one PUSCH (up to two PUSCH codewords, transmission of up to two uplink transport blocks) in one cell is defined. The That is, DCI format 4 is used for scheduling transmission (transmission mode) on PUSCH using a plurality of antenna ports.

  For example, the DCI format for uplink includes downlink control information such as information on PUSCH resource allocation and information on MCS (Modulation and Coding scheme). Further, the DCI format for the uplink may include information on the reference sequence index. Further, the DCI format for uplink may include information for instructing validity or invalidity of sequence group hopping and / or sequence hopping. Hereinafter, the DCI format used for PUSCH scheduling is also referred to as an uplink grant.

  The PDSCH is used for downlink data transmission. Furthermore, the PDSCH is used to notify (designate) a random access response grant to the terminal. Here, the random access response grant is used for PUSCH scheduling. Here, the random access response grant is instructed to the physical layer by an upper layer (for example, the MAC layer).

  For example, the base station transmits a random access response including the random access response grant in the random access response transmitted as the message 2 in the random access procedure. Further, the base station transmits a random access response grant corresponding to the message 1 transmitted by the terminal in the random access procedure. In addition, the base station transmits a random access response grant for transmission of message 3 in the random access procedure. That is, the random access response grant can be used to schedule a PUSCH for transmission of message 3 in a random access procedure.

  In FIG. 4, the terminal monitors a set of PDCCH candidates (PDCCH candidates). Here, the PDCCH candidate indicates a candidate in which the PDCCH may be arranged and transmitted by the base station. Moreover, a PDCCH candidate is comprised from one or several control channel element (CCE; Control Channel Element). In addition, monitoring means that the terminal attempts to decode each PDCCH in the set of PDCCH candidates according to all the DCI formats to be monitored. Here, the set of PDCCH candidates monitored by the terminal is also called a search space. That is, a search space is a set of resources that may be used for PDCCH transmission by a base station.

  Further, a common search space (CSS; Common Search Space) and a user equipment specific search space (USS; UE-Specific Search Space, a terminal-specific (terminal-specific) search space) are configured in the PDCCH resource region. (Defined and set).

  That is, in FIG. 4, CSS and / or USS are configured in the PDCCH resource region. Also, CSS and / or USS are configured in the resource region of E-PDCCH. The terminal monitors the PDCCH in the CSS and / or USS of the PDCCH resource area, and detects the PDCCH addressed to itself. In addition, the terminal monitors the E-PDCCH in the CSS and / or USS of the E-PDCCH resource region, and detects the PDCCH addressed to itself.

  Here, CSS is used for transmission of downlink control information to a plurality of terminals. That is, CSS is defined by resources common to a plurality of terminals. For example, the CSS is composed of CCEs having a predetermined number between the base station and the terminal. For example, the CSS is composed of CCEs having indexes from 0 to 15. Here, CSS may be used for transmission of downlink control information to a specific terminal. That is, the base station transmits a DCI format intended for a plurality of terminals and / or a DCI format intended for a specific terminal in the CSS.

  The USS is used for transmission of downlink control information to a specific terminal. That is, USS is defined by resources dedicated to a certain terminal. That is, USS is defined independently for each terminal. For example, the USS includes a radio network temporary identifier (RNTI) assigned by a base station, a slot number in a radio frame, a number of CCEs determined based on an aggregation level, and the like. Here, the RNTI includes C-RNTI (Cell RNTI) and Temporary C-RNTI. That is, the base station transmits a DCI format intended for a specific terminal in the USS.

  Here, RNTI assigned to the terminal by the base station is used for transmission of downlink control information (transmission on PDCCH). Specifically, a CRC (Cyclic Redundancy Check) generated based on downlink control information (which may be in a DCI format) is added to the downlink control information, After being added, the CRC parity bits are scrambled with the RNTI.

  The terminal tries to decode the downlink control information with CRC parity bits scrambled by RNTI, and detects the PDCCH for which the CRC was successful as the PDCCH addressed to itself (also referred to as blind decoding). Here, RNTI includes C-RNTI and Temporary C-RNTI. That is, the terminal decodes the PDCCH with CRC scrambled by C-RNTI. In addition, the terminal decodes the PDCCH accompanied by the CRC scrambled by the Temporary C-RNTI.

  Here, C-RNTI is a unique (unique) identifier used for RRC (Radio Resource Control) connection and scheduling identification. For example, C-RNTI is utilized for dynamically scheduled unicast transmissions.

  Temporary C-RNTI is an identifier used for a random access procedure. Here, the base station transmits the Temporary C-RNTI included in the random access response. For example, Temporary C-RNTI is used in a random access procedure to identify a terminal performing a random access procedure. Temporary C-RNTI is used for retransmission of message 3 in the random access procedure. That is, the base station transmits the downlink control information on the PDCCH with the CRC scrambled by the Temporary C-RNTI in order for the terminal to retransmit the message 3. That is, the terminal changes the interpretation of the downlink control information based on which RNTI the CRC is scrambled with.

  Here, for example, the terminal executes a random access procedure in order to synchronize with the base station in the time domain. In addition, the terminal performs a random access procedure to establish an initial connection establishment (initial connection establishment). The terminal also executes a random access procedure for handover. In addition, the terminal performs a random access procedure for connection re-establishment. In addition, the terminal executes a random access procedure to request UL-SCH resources.

  When the PDSCH resource is scheduled by the downlink control information transmitted on the PDCCH, the terminal receives the downlink data on the scheduled PDSCH. Also, when the PUSCH resource is scheduled by the downlink control information transmitted on the PDCCH, the terminal transmits uplink data and / or uplink control information on the scheduled PUSCH. Here, the first reference signal is multiplexed on the uplink data and / or uplink control information transmitted on the PUSCH.

  Also, the terminal transmits uplink control information using PUCCH. For example, the terminal transmits information indicating ACK / NACK for downlink data (HARQ; also called ACK / NACK in Hybrid Automatic Repeat Request) using PUCCH. Here, the terminal corresponds to the number of the first CCE used to transmit the PDCCH (used to transmit the downlink assignment) (also referred to as the lowest CCE index used to configure the PDCCH). The uplink control information is transmitted using the PUCCH resource to be used. Here, the second reference signal is multiplexed for transmission of the uplink control information transmitted on the PUCCH.

  In addition, the base station and the terminal transmit and receive signals in an upper layer (Higher layer). For example, the base station and the terminal are also referred to as a radio resource control signal (RRC signaling; Radio Resource Control signal, RRC message; Radio Resource Control message, RRC information; Radio Resource Control information) in the RRC layer (Layer 3). Send and receive. Here, in the RRC layer, a dedicated signal transmitted to a certain terminal by the base station is also referred to as a dedicated signal. That is, a setting (information) unique (specific) to a certain terminal is notified by a base station using a dedicated signal.

  Further, the base station and the terminal transmit and receive MAC control elements in a MAC (Media Access Control) layer (layer 2). Here, the RRC signaling and / or the MAC control element is also referred to as a higher layer signaling.

An example of a method for generating the reference signal sequence r ^(α) _{u, ν} will be described below. Here, the reference signal sequence is used to generate a first reference signal sequence. The reference signal sequence is used to generate a second reference signal sequence. For example, the reference signal sequence is defined according to Equation 1 by cyclic shift of the reference sequence r￣ ^(α) _{u, ν} (n).

Formula 1

That is, a cyclic shift α is applied to the reference sequence, and a reference signal sequence is generated. Further, a plurality of reference signal sequences are defined from a single reference sequence by different cyclic shift α values. Here, M _SC ^RS is the length of the reference signal sequence, and is represented by, for example, M _SC ^RS = mN _SC ^RB . N _SC ^RB is the size of the resource block in the frequency domain, and is represented by the number of subcarriers, for example.

  The reference series is divided into groups. That is, the reference sequence is represented by a group number (also referred to as a sequence group number) u and a reference sequence number ν in the group. For example, the reference sequence is divided into 30 groups, and each group includes two reference sequences. Also, sequence group hopping is applied to 30 groups. In addition, sequence hopping is applied to two reference sequences in one group.

Here, each of the sequence group number u and the reference sequence number ν can change in time. The definition of the reference sequence depends on the sequence length M _SC ^RS . For example, when M _SC ^RS ≧ 3N _SC ^RB , the reference sequence is given by Equation 2.

Formula 2

Here, the q-th root Zadoff-Chu sequence x _q (m) is defined by Equation 3.

Formula 3

  Here, q is given by Equation 4.

Formula 4

Here, the length N _ZC ^RS of the Zadoff-Chu sequence is given by the maximum prime number that satisfies N _ZC ^RS <M _SC ^RS .

Further, the sequence group number u in slot _{n s} is the group hopping pattern _f gh _{(n s)} and sequence shift pattern _{f ss,} defined according to Equation 5.

Formula 5

  Here, the base station can instruct the terminal to enable or disable sequence group hopping (also simply referred to as group hopping). As will be described later, for example, when the condition is A, the base station can instruct validity / invalidity of sequence group hopping based on a cell-specific parameter (cell-specific). Further, when the condition is B, the base station can instruct validity / invalidity of sequence group hopping based on parameters specific to the terminal (user equipment specific; UE-specific). Here, details of condition A and condition B will be described later.

  For example, when the terminal is instructed to enable sequence group hopping by the base station, the terminal hops a group of reference signal sequences for each slot. That is, the terminal determines whether or not to hop a group of reference signal sequences for each slot according to validity or invalidity of sequence group hopping.

Here, for example, group hopping pattern _f gh _{(n s)} is the same for PUSCH and PUCCH, given by Equation 6.

Formula 6

  Here, the pseudo-random sequence c (i) is defined by Equation 7. For example, the pseudo-random sequence is defined by a gold sequence of length 31 and is given by Equation 7.

Formula 7

Here, for example, N _c = 1600. Also, the first m-sequence x ₁ is initialized by x ₁ (0) = 1, x ₁ (n) = 0, n = 1, 2,. The second m-sequence _{x 2} is initialized by Equation 8.

Formula 8

Here, c _init is defined by Equation 9. That is, the pseudo-random sequence of group hopping pattern _f gh _{(n s)} is initialized by Equation 9.

Formula 9

Details of the physical layer cell identity N _ID ^cell and the parameter “X” will be described later.

Also, the definition of the sequence shift pattern f _ss is different between PUSCH and PUCCH. For example, for PUCCH, the sequence shift pattern f _ss ^PUCCH is given by Equation 10. Also, the sequence shift pattern f _ss ^PUSCH is given by Equation 11 with respect to ^PUSCH .

Formula 10

Formula 11

Details of the physical layer cell identity N _ID ^cell and the parameter “X” will be described later. Details of the parameter _Δss and the parameter “Y” will be described later.

Also, the reference sequence number ν within the reference sequence group in slot n _s, is defined by Equation 12. Here, sequence hopping may be applied only to a reference signal having a length of 6N _SC ^RB or more. That is, for the reference signal length less than 6N _SC ^RB , the reference sequence number ν is given by ν = 0.

Formula 12

  Here, the base station can instruct the terminal whether the sequence hopping is valid or invalid. As will be described later, for example, when the condition is A, the base station can instruct validity / invalidity of sequence hopping based on a cell-specific parameter. Further, when the condition is B, the base station can instruct validity / invalidity of sequence hopping based on the parameters specific to the terminal. Here, details of condition A and condition B will be described later.

  For example, if the terminal is instructed to enable sequence hopping by the base station, the terminal hops the sequence for each slot within the group. That is, the terminal determines whether or not to hop a sequence for each slot in the group in accordance with validity or invalidity of sequence hopping.

Here, the pseudo-random sequence c (i) is defined by Equation 7 and Equation 8. C _init is defined by Equation 13. That is, the pseudo-random sequence with the reference sequence number ν is initialized by Equation 13.

Formula 13

Here, details of the physical cell identity N _ID ^cell and the parameter “X” will be described later.

An example of a method for generating a first reference signal sequence will be described below. That is, a method for generating a demodulation reference signal for PUSCH is described. For example, the demodulation reference signal sequence γ ^(λ) _PUSCH (·) of _PUSCH related to the layer λε {0, 1,.

Formula 14

Here, υ indicates the number of transmission layers. For example, it is indicated by m = 0 or 1. Also, n = 0,..., Indicated by M _SC ^RS −1. Also, M _SC ^RS = M _SC ^PUSCH . Here, M _SC ^PUSCH is a bandwidth scheduled by the base station for uplink transmission (transmission on PUSCH), and is represented by, for example, the number of subcarriers. Furthermore, w ^(λ) (m) represents an orthologous sequence.

Further, the cyclic shift alpha _lambda at slot _{n s, α λ = 2πn cs} , given by _lambda. Here, n _{cs and λ} are expressed by Equation 15. That is, the cyclic shift applied to the first reference signal related to PUSCH is defined by Equation 15.

Formula 15

Here, the n ⁽¹⁾ _DMRS is notified by the base station apparatus using an upper layer signal. Also, n ⁽²⁾ _{DMRS, λ} is instructed by the base station apparatus using the DCI format. The quantity n _PN (n _s ) is given by Equation 16.

Formula 16

Here, the pseudo-random sequence c (i) is defined by Equation 7 and Equation 8. C _init is defined by Equation 17. That is, the cyclic shift applied to the first reference signal related to PUSCH is initialized by Equation 17.

Formula 17

Details of the physical layer cell identity N _ID ^cell and the parameter “Z” will be described later.

Hereinafter, an example of a method for generating the second reference signal sequence will be described. That is, a method for generating a demodulation reference signal for PUCCH will be described. For example, PUCCH demodulation reference signal sequence γ ^(P) _PUCCH (·) is defined by Equation 18.

Formula 18

Here, for example, m = 0,..., ^Indicated by M _RS ^PUCCH −1. Also, n = 0,..., Indicated by M _RS −1. It is indicated by m ′ = 0 or 1. Here, p is the number of antenna ports used for PUCCH transmission (transmission on PUCCH). Further, the sequence γ ^(αp) _{u, v} (n) is given by Equation 1, for example, M _SC ^RS = 12.

Here, the cyclic shift α _P ( _ns, l) is given by Equation 19. That is, the cyclic shift applied to the second reference signal related to PUCCH is defined by Equation 19.

Formula 19

Here, n ′ _P (n _s ), N ′, and Δ _shift ^PUCCH are determined based on information notified by the base station. Also, the number of reference symbols and the sequence w (n) around the slot M _RS ^PUCCH are defined by specifications and the like.

The cyclic shift n _cs ^cell ( _ns, l) is defined by Equation 20.

Formula 20

Here, N _sym ^UL is the number of symbols in the uplink slot (number of SC-FDMA symbols). The pseudo-random sequence c (i) is defined by Equation 7 and Equation 8. C _init is defined by Equation 21 or Equation 22. That is, the cyclic shift applied to the second reference signal related to PUCCH is initialized by Equation 21 or Equation 22.

Formula 21

Formula 22

Details of the physical layer cell identity N _ID ^cell and the parameter “X” will be described later. Details of the parameter “K” will be described later. Here, by defining c _init with Equation 21, the same parameter “X” can be used for the generation of the first reference signal and the generation of the second reference signal. That is, the parameter “X” used for generating the first reference signal can be used for generating the second reference signal, and the parameter can be set using the radio resource efficiently. it can.

Here, the cyclic shift applied to the PUCCH is generated using Equation 20. C _init is defined by Equation 21 or Equation 22. That is, the terminal can transmit the uplink signal generated using Equation 20 and Equation 21 on the PUCCH. Or a terminal can transmit the uplink signal produced | generated using Numerical formula 20 and Numerical formula 22 by PUCCH.

Here, in the above formula, N _ID ^cell indicates a physical layer cell identity (also referred to as a physical layer cell identity). That is, the N _ID ^cell indicates a cell (base station) specific (cell (base station) specific) identity. That is, the N _ID ^cell indicates the physical layer identity of the cell. For example, the N _ID ^cell may be an N _ID ^cell corresponding to the primary cell.

For example, the terminal can detect the N _ID ^cell using a synchronization signal (Synchronization signals). Also, the terminal can obtain the N _ID ^cell from information included in a higher layer signal (for example, a band over command) transmitted by the base station.

That is, N _ID ^cell is a parameter related to the reference signal sequence (parameter related to generation of the reference signal sequence). That is, N _ID ^cell is a parameter related to the first reference signal (parameter related to generation of the first reference signal sequence). N _ID ^cell is a parameter related to the second reference signal (parameter related to generation of the second reference signal sequence). N _ID ^cell is a parameter related to PUCCH (a parameter related to generation of an uplink signal transmitted on PUCCH).

Further, in the above formula, for example, the parameter Δ _ss is represented by Δ _ss ε {0, 1,. Here, the parameter Δ _ss is a parameter specific to the cell (base station). For example, the terminal can receive the parameter Δ _ss using SIB2 (System Information Block Type 2). Here, SIB2 is a common setting (common information) for all terminals (may be a plurality of terminals) in the cell.

That is, the terminal is assigned the parameter Δ _ss using information common to all terminals in the cell. That is, the parameter Δ _ss is a parameter related to the first reference signal.

  In the above formula, the parameter “X” (the value of the parameter “X”) indicates a virtual cell identity (also referred to as a virtual cell identity). That is, the parameter “X” indicates a terminal-specific identity. That is, the parameter “X” indicates a parameter specific to the terminal.

  That is, the parameter “X” is a parameter related to the reference signal sequence. That is, the parameter “X” is a parameter related to the first reference signal. The parameter “X” is a parameter related to the second reference signal. The parameter “X” is a parameter related to PUCCH.

  In the above formula, for example, the parameter “Y” (value of the parameter “Y”) is indicated by “Y” ε {0, 1,..., 29}. Here, the parameter “Y” indicates a parameter unique to the terminal. That is, the parameter “Y” is a parameter related to the first reference signal.

  In the above formula, the parameter “Z” (value of the parameter “Z”) indicates the initial value of the second m-sequence. Here, the parameter “Z” indicates a parameter specific to the terminal. That is, the parameter “Z” is a parameter related to the first reference signal.

  In the above formula, the parameter “K” (value of the parameter “K”) represents the initial value of the second m-sequence. Here, the parameter “K” indicates a parameter unique to the terminal. That is, the parameter “K” is a parameter related to PUCCH.

  In the above formula, the parameter “M” (the value of the parameter “M”) is used to instruct validity / invalidity of sequence group hopping and / or sequence hopping. For example, when sequence group hopping and / or sequence hopping is enabled, the parameter “M” is set to “1”. When sequence group hopping and / or sequence hopping is invalid, the parameter “M” is set to “0”. Here, the parameter “M” indicates a parameter specific to the terminal.

  That is, the parameter “M” is a parameter related to the reference signal sequence. That is, the parameter “M” is a parameter related to the first reference signal. The parameter “M” is a parameter related to the second reference signal.

  Here, the base station can set the parameter “X” in the terminal using the higher layer signal. For example, the base station can set the parameter “X” using a dedicated signal. Further, the base station sets a plurality of parameters “X” using a dedicated signal, and downlink control information transmitted from the set plurality of parameters “X” by one PDCCH. (For example, the information about the reference sequence index or the reference sequence index related to PUCCH) may be used to indicate.

  That is, downlink control information for indicating the parameter “X” is included in the uplink grant. Further, downlink control information for instructing the parameter “X” may be included in the downlink assignment.

For example, the base station sets (X ₀ ) and (X ₁ ) as a plurality of parameters “X”, and uses downlink control information (for example, 1-bit information) transmitted on the PDCCH, and ₀ ) or (X ₁ ) can be indicated.

  Further, the base station can set the parameter “Y” in the terminal using the higher layer signal. For example, the base station can set the parameter “Y” using a dedicated signal. Also, the base station sets a plurality of parameters “Y” using a dedicated signal, and one parameter “Y” from among the plurality of set parameters “Y” is transmitted on the PDCCH. (For example, information regarding the reference sequence index) may be used for the instruction. That is, downlink control information for indicating the parameter “Y” is included in the uplink grant.

For example, the base station sets (Y ₀ ) and (Y ₁ ) as a plurality of parameters “Y”, and uses downlink control information (for example, 1-bit information) transmitted on the PDCCH, and (Y ₀ ) or (Y ₁ ) can be indicated.

  Further, the base station can set the parameter “Z” in the terminal using the higher layer signal. For example, the base station can set the parameter “Z” using a dedicated signal. Also, the base station sets a plurality of parameters “Z” using a dedicated signal, and one parameter “Z” from among the set parameters “Z” is transmitted on the PDCCH. (For example, information regarding the reference sequence index) may be used for the instruction. That is, downlink control information for indicating the parameter “Z” is included in the uplink grant.

For example, the base station sets (Z ₀ ) and (Z ₁ ) as a plurality of parameters “Z”, and uses downlink control information (for example, 1-bit information) transmitted on the PDCCH, to ₀ ) or (Z ₁ ) can be indicated.

  Further, the base station can set the parameter “K” in the terminal using the higher layer signal. For example, the base station can set the parameter “K” using a dedicated signal. Also, the base station sets a plurality of parameters “K” using a dedicated signal, and downlink control information transmitted from the set plurality of parameters “K” by one PDCCH. (For example, information regarding a reference sequence index related to PUCCH) may be used to indicate. That is, downlink control information for indicating the parameter “K” is included in the downlink assignment.

For example, the base station sets (K ₀ ) and (K ₁ ) as a plurality of parameters “K”, and uses downlink control information (for example, 1-bit information) transmitted on the PDCCH, to (K ₀ ) or (K ₁ ) can be indicated.

  Further, the base station can set the parameter “M” in the terminal using the higher layer signal. For example, the base station can set the parameter “M” using a dedicated signal. In addition, the base station sets a plurality of parameters “M” using a dedicated signal, and downlink control information transmitted from the set plurality of parameters “M” by one parameter “M” using PDCCH. (For example, information for instructing validity or invalidity of sequence group hopping and / or sequence hopping) may be used. That is, downlink control information for indicating the parameter “M” is included in the uplink grant.

For example, the base station sets (M ₀ ) and (M ₁ ) as a plurality of parameters “M”, and uses the downlink control information (for example, 1-bit information) transmitted on the PDCCH, (M ₀ ) or (M ₁ ) can be indicated.

  In addition, the base station may use a plurality of sets of parameter “X” and / or parameter “Y” and / or parameter “Z” and / or parameter “K” and / or parameter “M” using a dedicated signal. Downlink control information (for example, information related to a reference sequence index, information related to a reference sequence index related to PUCCH, sequence group hopping, and group control hopping). The information may also be indicated using information for indicating validity / invalidity of sequence hopping.

  That is, downlink control information for indicating one set from among a plurality of sets is included in the uplink grant. Further, downlink control information for indicating one set from among a plurality of sets may be included in the downlink assignment.

  Here, the parameter “X”, the parameter “Y”, the parameter “Z”, the parameter “K”, and the parameter “M” may be set independently. The parameter “X” and / or the parameter “Y” and / or the parameter “Z” and / or the parameter “K” may be set in association with each other. For example, the base station notifies only the parameter “X” to the terminal, whereby the parameter “Y” and / or the parameter “Z” and / or the parameter “K” and / or the parameter “ M ″ can be indicated.

  Here, for example, the association between the parameter “X”, the parameter “Y” and / or the parameter “Z” and / or the parameter “K” and / or the parameter “M” is defined in advance according to the specification, etc. This can be known information in the terminal.

  Hereinafter, for ease of explanation, a case where a parameter set includes a parameter “X”, a parameter “Y”, a parameter “Z”, and a parameter “K” will be described. The same embodiment can be applied to the case where the parameter “Y” and / or the parameter “Z” and / or the parameter “K” are included.

For example, the base station sets (X _0, Y _0, Z _0, K ₀ ) and (X _1, Y _1, Z _1, K ₁ ) as multiple sets of parameters, and is transmitted on the PDCCH. Control information (eg, 1-bit information) can be used to indicate (X _0, Y _0, Z _0, K ₀ ) or (X _1, Y _1, Z _1, K ₁ ).

When the parameters (X _0, Y _0, Z _0, K ₀ ) are indicated by the downlink control information transmitted on the PDCCH, the terminal uses the parameters (X _0, Y _0, Z _0, K ₀ ). Is used to generate the first reference signal. The terminal, the downlink control information transmitted by PDCCH, if the parameter _{(X 1, Y 1, Z} 1, K 1) is instructed, the parameters _{(X 1, Y 1, Z} 1, K ₁ ) is used to generate the first reference signal.

In addition, when parameters (X _0, Y _0, Z _0, K ₀ ) are indicated by the downlink control information transmitted on the PDCCH, the terminal uses the parameters (X _0, Y _0, Z _0, K ₀ ) is used to generate the second reference signal. The terminal, the downlink control information transmitted by PDCCH, if the parameter _{(X 1, Y 1, Z} 1, K 1) is instructed, the parameters _{(X 1, Y 1, Z} 1, K ₁ ) is used to generate a second reference signal.

Here, the base station can transmit the parameter “M” in each of the parameter sets. That is, the base station can instruct each group of parameters whether sequence group hopping and / or sequence hopping is enabled or disabled. For example, the base station may use (X _0, Y _0, Z _0, M ₀ = “1” (valid)) and (X _1, Y _1, Z _1, M ₁ = “0” as a plurality of sets of parameters. (Invalid)) and using downlink control information (for example, 1-bit information) transmitted on the PDCCH, (X _0, Y _0, Z _0, M ₀ = “1” (valid)) or _{(X 1, Y 1, Z} 1, M 1 = "0" ( invalid)) can be instructed.

When parameters (X _0, Y _0, Z _0, M ₀ = “1” (valid)) are instructed by downlink control information transmitted on the PDCCH, the terminal uses the parameters (X _0, Y _{0 ,} Z ₀ ) and enabling sequence group hopping to generate the first reference signal. The terminal, the downlink control information transmitted by PDCCH, if the parameter _{(X 1, Y 1, Z} 1, M 1 = "0" (the disabled)) is instructed, the parameters _{(X 1,} Y _1, Z ₁ ) is used and sequence group hopping is disabled to generate the first reference signal.

  Hereinafter, for ease of explanation, downlink control information for instructing the parameter “X” and / or downlink control information for instructing the parameter “Y” and / or the parameter “Z”. The downlink control information for instructing the parameter and / or the downlink control information for instructing the parameter “K” and / or the downlink control information for instructing the set of parameters, the parameter is indicated For downlink control information.

  Here, the downlink control information for indicating the parameter may be included in the uplink grant only when the parameter is set by the base station using the higher layer signal. Also, the downlink control information for indicating the parameter may be included in the downlink assignment only when the parameter is set by the base station using the higher layer signal.

  For example, the base station can indicate whether or not downlink control information for indicating a parameter is included in the uplink grant using a dedicated signal. Also, the base station can instruct whether downlink control information for indicating a parameter is included in the downlink assignment using a dedicated signal.

  In addition, the base station indicates a parameter by setting a downlink transmission mode (for example, a transmission mode in PDSCH) and / or an uplink transmission mode (for example, a transmission mode in PUSCH) using a dedicated signal. Whether or not the downlink control information to be included in the uplink grant can be instructed. Further, the base station includes downlink control information for indicating parameters by setting a downlink transmission mode and / or an uplink transmission mode using a dedicated signal, in the downlink assignment. Whether or not can be instructed.

  That is, the terminal identifies that downlink control information for indicating a parameter is included in the uplink grant only when a specific downlink transmission mode and / or uplink transmission mode is set. can do. Also, the terminal assigns that downlink control information for indicating parameters is included in the downlink assignment only when a specific downlink transmission mode and / or uplink transmission mode is set. Can be identified.

  Here, a specific downlink transmission mode and / or uplink transmission mode is defined in advance by specifications or the like, and can be known information between the base station and the terminal.

  Further, the base station determines that the downlink control information for indicating the parameter is included in the uplink grant and that the downlink control information for indicating the parameter is included in the downlink assignment. Information may be used to set (instruct). For example, the base station can transmit a single piece of information using a dedicated signal. Also, the base station can transmit the downlink transmission mode and / or the uplink transmission mode as a single piece of information.

  Further, the base station may include the downlink control information for instructing the parameter only in the uplink grant transmitted in the user apparatus specific search space. Further, the base station may include the downlink control information for indicating the parameter only in the downlink assignment transmitted in the user apparatus specific search space.

  Here, a default value may be set in downlink control information for indicating a parameter. That is, the terminal can use the default value until set by the base station. Here, the default value is defined in advance by specifications or the like and can be known information between the base station and the terminal.

For example, the default value of the parameter “X” may be N _ID ^cell . The parameter default values for "Y" may be a value of the parameter delta _ss. Further, the default value of the parameter “Y” may be specified by the base station using SIB2. The default value of the parameter “Y” may be “0”. Further, the default value of the parameter “Z” may be calculated according to Equation 17 (1). Here, f _ss ^PUSCH in Expression 17 (1) may be calculated based on the parameter Δ _ss designated by the base station using SIB2. The default value of the parameter “K” may be N _ID ^cell (for example, N _ID ^cell corresponding to the primary ^cell ). The default value of the parameter “M” may be “invalid”.

Hereinafter, the physical layer cell identity N _ID ^cell and / or the parameter Δ _ss is also referred to as a first parameter. The parameter “X” and / or the parameter “Y” and / or the parameter “Z” and / or the parameter “K” and / or the parameter “M” are also described as the second parameter.

  Here, as illustrated in FIG. 5, the terminal identifies a condition and switches a parameter related to the first reference signal (which may generate a first reference signal sequence) based on the condition. That is, when the condition is A, the terminal generates the first reference signal using the first parameter in the above formula.

  Further, the terminal identifies the condition, and switches a parameter related to the second reference signal (may generate a second reference signal sequence) based on the condition. That is, when the condition is A, the terminal generates the second reference signal using the first parameter in the above formula.

  Further, the terminal identifies the condition, and switches a parameter related to PUCCH (may generate an uplink signal transmitted by PUCCH) based on the condition. That is, when the condition is A, the terminal generates an uplink signal transmitted on the PUCCH using the first parameter in the above formula.

  That is, when the condition is A, the terminal transmits the first reference signal (which may be a part of the first reference signal sequence) generated by using the first parameter to the PUSCH (PUSCH). To a resource element in a resource block allocated for transmission).

  In addition, when the condition is A, the terminal transmits the second reference signal generated using the first parameter (which may be a part of the second reference signal sequence) to PUCCH transmission (in PUCCH). To a resource element in a resource block allocated for transmission).

  In addition, when the condition is A, the terminal transmits the uplink signal generated using the first parameter to the resource element in the resource block allocated for PUCCH transmission (transmission on PUCCH). Map.

  Further, the base station identifies the condition, and switches a parameter related to the first reference signal (which may generate the first reference signal sequence) based on the condition. That is, when the condition is A, the base station assumes that the first reference signal is generated using the first parameter in the above formula.

  Further, the base station identifies the condition, and switches a parameter related to the second reference signal (may generate a second reference signal sequence) based on the condition. That is, when the condition is A, the base station assumes that the second reference signal is generated using the first parameter in the above formula.

  Further, the base station identifies the condition, and switches a parameter related to PUCCH (may generate an uplink signal transmitted by PUCCH) based on the condition. That is, when the condition is A, the base station assumes that an uplink signal transmitted on the PUCCH is generated using the first parameter in the above formula.

  That is, when the condition is A, the base station transmits the first reference signal (which may be part of the first reference signal sequence) generated using the first parameter to the PUSCH ( Assume that it is mapped to a resource element in a resource block allocated for transmission on the PUSCH.

  When the condition is A, the base station transmits the second reference signal generated using the first parameter (may be a part of the second reference signal sequence) to transmit the PUCCH ( Assume that it is mapped to a resource element in the resource block allocated for transmission on the PUCCH.

  In addition, when the condition is A, the base station uses the resource in the resource block to which the uplink signal generated using the first parameter is allocated for PUCCH transmission (transmission on PUCCH). Assume that it is mapped to an element.

  Further, when the condition is B, the terminal generates the first reference signal using the second parameter in the above formula. Further, when the condition is B, the terminal generates the second reference signal using the second parameter in the above formula. Further, when the condition is B, the terminal generates an uplink signal transmitted on the PUCCH using the second parameter in the above formula.

  That is, when the condition is B, the terminal transmits the first reference signal (which may be a part of the first reference signal sequence) generated by using the second parameter to the PUSCH transmission (PUSCH). To a resource element in a resource block allocated for transmission).

  When the condition is B, the terminal transmits the second reference signal (which may be a part of the second reference signal sequence) generated using the second parameter to PUCCH transmission (in PUCCH). To a resource element in a resource block allocated for transmission).

  In addition, when the condition is B, the terminal transmits the uplink signal generated using the second parameter to the resource element in the resource block allocated for PUCCH transmission (transmission on PUCCH). Map.

  In addition, when the condition is B, the base station assumes that the first reference signal is generated using the second parameter in the above formula. In addition, when the condition is B, the terminal assumes that the second reference signal is generated using the second parameter in the above formula. In addition, when the condition is B, the terminal assumes that an uplink signal transmitted on the PUCCH is generated using the second parameter in the above formula.

  That is, when the condition is B, the base station transmits the first reference signal (which may be part of the first reference signal sequence) generated using the second parameter to the PUSCH ( Assume that it is mapped to a resource element in a resource block allocated for transmission on the PUSCH.

  In addition, when the condition is B, the base station transmits the second reference signal (which may be part of the second reference signal sequence) generated using the second parameter to the PUCCH transmission ( Assume that it is mapped to a resource element in the resource block allocated for transmission on the PUCCH.

  In addition, when the condition is B, the base station uses the resource in the resource block to which the uplink signal generated using the second parameter is allocated for PUCCH transmission (transmission on PUCCH). Assume that it is mapped to an element.

  Here, the condition A includes the detection (decoding) of the PDCCH in the CSS. That is, when the terminal detects PDCCH in CSS, the terminal transmits the first reference signal generated using the first parameter. Further, when the terminal detects PDCCH in CSS, the terminal transmits a second reference signal generated using the first parameter. Further, when the terminal detects PDCCH in CSS, the terminal transmits an uplink signal generated using the first parameter on PUCCH.

  Also, when the PDCCH is arranged in the CSS, the base station receives the second reference signal generated using the first parameter. Also, when the PDCCH is arranged in the CSS, the base station receives the second reference signal generated using the first parameter. Moreover, when PDCCH is arrange | positioned in CSS, a base station receives the uplink signal produced | generated using the 1st parameter by PUCCH.

That is, when a terminal detects a PDCCH in CSS, the terminal transmits a first reference signal generated using an N _ID ^cell . Further, when the terminal detects the PDCCH in the CSS, the terminal transmits a second reference signal generated using the N _ID ^cell . Further, when the terminal detects PDCCH in CSS, the terminal transmits an uplink signal generated using N _ID ^cell by PUCCH. In addition, when the terminal detects the PDCCH in the CSS, the terminal transmits a first reference signal generated using the parameter Δ _ss .

  Condition B includes detecting (decoding) the PDCCH in the USS. That is, when the terminal detects PDCCH in USS, the terminal transmits the first reference signal generated using the second parameter. Further, when the terminal detects PDCCH in USS, the terminal transmits a second reference signal generated using the second parameter. Further, when the terminal detects PDCCH in USS, the terminal transmits an uplink signal generated using the second parameter on PUCCH.

  Also, when the PDCCH is arranged in the USS, the base station receives the first reference signal generated using the second parameter. In addition, when the PDCCH is arranged in the USS, the base station receives the second reference signal generated using the second parameter. Moreover, when PDCCH is arrange | positioned in USS, a base station receives the uplink signal produced | generated using the 2nd parameter by PUCCH.

  That is, when the terminal detects the PDCCH in the USS, the terminal transmits the first reference signal generated using the parameter “X”. Further, when the terminal detects the PDCCH in the USS, the terminal transmits the first reference signal generated using the parameter “Y”. Further, when the terminal detects the PDCCH in the USS, the terminal transmits the first reference signal generated using the parameter “Z”.

  Further, when the terminal detects the PDCCH in the USS, the terminal transmits a second reference signal generated using the parameter “X”. Further, when the terminal detects PDCCH in USS, the terminal transmits an uplink signal generated using parameter “X” on PUCCH. Further, when the terminal detects PDCCH in the USS, the terminal transmits an uplink signal generated using the parameter “K” on PUCCH.

  Here, downlink control information (for example, information on a reference sequence index, information on a reference sequence index related to PUCCH) for indicating a parameter is transmitted on the PDCCH in the USS.

  That is, the terminal transmits a first reference signal generated by a different method (using different parameters) to the base station based on the search space in which the PDCCH is detected. That is, the terminal generates the first reference signal by a different method based on whether PDCCH is detected in CSS or USS.

  Further, the terminal transmits a second reference signal generated by a different method to the base station based on the search space in which the PDCCH is detected. That is, the terminal generates the second reference signal by a different method based on whether PDCCH is detected in CSS or USS.

  Also, the terminal transmits an uplink signal generated by a different method on the PUCCH based on the search space in which the PDCCH is detected. That is, the terminal transmits an uplink signal generated by a different method on the PUCCH based on whether the PDCCH is detected in the CSS or the USS.

  That is, when the terminal detects PDCCH by CSS, it transmits a reference signal related to the transmission of the physical uplink channel generated using the first parameter, and when PDCCH is detected by USS. The reference signal related to the transmission of the physical uplink channel generated using the second parameter is transmitted.

  In addition, when the PDCCH is arranged in the CSS, the base station receives a reference signal related to the transmission of the physical uplink channel generated using the first parameter, and arranges the PDCCH in the USS. Receives a reference signal related to the transmission of the physical uplink channel, generated using the second parameter.

  Here, the physical uplink channel includes PUSCH. The physical uplink channel includes PUCCH.

  The condition A includes detecting (decoding) a PDCCH with a CRC scrambled by the Temporary C-RNTI. That is, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits a first reference signal generated using the first parameter. Further, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits a second reference signal generated using the first parameter. Also, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits an uplink signal generated using the first parameter on the PUCCH.

  Further, when the PDCCH with CRC scrambled by Temporary C-RNTI is arranged, the base station receives the first reference signal generated using the first parameter. In addition, when the PDCCH with CRC scrambled by Temporary C-RNTI is arranged, the base station receives the second reference signal generated using the first parameter. Further, when the PDCCH with CRC scrambled by Temporary C-RNTI is arranged, the base station receives the uplink signal generated using the first parameter on the PUCCH.

That is, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits a first reference signal generated using the N _ID ^cell . Further, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits a second reference signal generated using the N _ID ^cell . Also, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits an uplink signal generated using the N _ID ^cell by PUCCH. Further, when the terminal detects a PDCCH with a CRC scrambled by Temporary C-RNTI, the terminal transmits a first reference signal generated using the parameter Δ _ss .

  Further, the condition B includes detecting (decoding) a PDCCH accompanied by a CRC scrambled by C-RNTI. That is, when a terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits a first reference signal generated using the second parameter. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits a second reference signal generated using the second parameter. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits an uplink signal generated using the second parameter on the PUCCH.

  In addition, when the PDCCH with CRC scrambled by C-RNTI is arranged, the base station receives the first reference signal generated using the second parameter. In addition, when the PDCCH with CRC scrambled by C-RNTI is arranged, the base station receives the second reference signal generated using the second parameter. Further, when the PDCCH with the CRC scrambled by the C-RNTI is arranged, the base station receives the uplink signal generated using the second parameter on the PUCCH.

  That is, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits a first reference signal generated using the parameter “X”. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits a first reference signal generated using the parameter “Y”. Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits a first reference signal generated using the parameter “Z”.

  Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits a second reference signal generated using the parameter “X”. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits an uplink signal generated using the parameter “X” on the PUCCH. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI, the terminal transmits an uplink signal generated using the parameter “K” on the PUCCH.

  Here, downlink control information (for example, information on a reference sequence index, information on a reference sequence index related to PUCCH) for indicating a parameter is transmitted on a PDCCH with a CRC scrambled by C-RNTI.

  That is, the terminal transmits a first reference signal generated in a different manner (using different parameters) to the base station based on the RNTI in which the CRC is scrambled. That is, the terminal generates the first reference signal in a different manner based on whether the CRC is scrambled by Temporary C-RNTI or scrambled by C-RNTI.

  Also, the terminal transmits a second reference signal generated by a different method to the base station based on the RNTI in which the CRC is scrambled. That is, the terminal generates the second reference signal in a different manner based on whether the CRC is scrambled by Temporary C-RNTI or scrambled by C-RNTI.

  Also, the terminal transmits an uplink signal generated by a different method on the PUCCH based on the RNTI in which the CRC is scrambled. That is, the terminal generates a PUCCH signal in a different manner based on whether the CRC is scrambled by Temporary C-RNTI or scrambled by C-RNTI.

  Further, the condition A may include detecting (decoding) a PDCCH accompanied by a CRC scrambled by C-RNTI or Temporary C-RNTI in CSS. That is, when detecting a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI in the CSS, the terminal transmits a first reference signal generated using the first parameter. Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI in the CSS, the terminal transmits a second reference signal generated using the first parameter. Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI in CSS, the terminal transmits an uplink signal generated using the first parameter on PUCCH.

  In addition, when a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI is arranged in the CSS, the base station receives the first reference signal generated using the first parameter. To do. In addition, when a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI is arranged in CSS, the base station receives the second reference signal generated using the first parameter. To do. In addition, when the PDCCH with CRC scrambled by C-RNTI or Temporary C-RNTI is arranged in CSS, the base station receives the uplink signal generated using the first parameter on PUCCH. To do.

That is, when a terminal detects a PDCCH with CRC scrambled by C-RNTI or Temporary C-RNTI in the CSS, the terminal transmits a first reference signal generated using the N _ID ^cell . Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI in the CSS, the terminal transmits a second reference signal generated using the N _ID ^cell . Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI or Temporary C-RNTI in CSS, the terminal transmits an uplink signal generated using the N _ID ^cell by PUCCH. The terminal, in CSS, when detecting a PDCCH with the CRC scrambled by the C-RNTI or the Temporary C-RNTI transmits a first reference signal generated using the parameter delta _ss.

  Further, the condition B may be included by detecting (decoding) a PDCCH with a CRC scrambled by C-RNTI in USS. Here, for example, the PDCCH with CRC scrambled by Temporary C-RNTI is arranged only in CSS. That is, when a terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits a first reference signal generated using the second parameter. Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits a second reference signal generated using the second parameter. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits an uplink signal generated using the second parameter on the PUCCH.

  In addition, when a PDCCH with a CRC scrambled by C-RNTI is arranged in the USS, the base station receives the first reference signal generated using the second parameter. In addition, when a PDCCH with a CRC scrambled by C-RNTI is arranged in the USS, the base station receives a second reference signal generated using the second parameter. In addition, when a PDCCH with a CRC scrambled by C-RNTI is arranged in the USS, the base station receives an uplink signal generated using the second parameter on the PUCCH.

  That is, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits a first reference signal generated using the parameter “X”. Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits a first reference signal generated using the parameter “Y”. Also, when the terminal detects a PDCCH with CRC scrambled by C-RNTI in the USS, the terminal transmits a first reference signal generated using the parameter “Z”.

  Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits a second reference signal generated using the parameter “X”. Also, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits an uplink signal generated using the parameter “X” on the PUCCH. Further, when the terminal detects a PDCCH with a CRC scrambled by C-RNTI in the USS, the terminal transmits an uplink signal generated using the parameter “K” on the PUCCH.

  Here, downlink control information (for example, information on a reference sequence index and information on a reference sequence index related to PUCCH) for indicating a parameter is transmitted on a PDCCH with a CRC scrambled by C-RNTI in USS. Is done.

  That is, the terminal transmits a first reference signal generated by a different method (using different parameters) to the base station based on the search space where the PDCCH is detected and the RNTI scrambled to the CRC. Also, the terminal transmits a second reference signal generated by a different method to the base station based on the search space in which the PDCCH is detected and the RNTI scrambled to the CRC. In addition, the terminal transmits, on the PUCCH, an uplink signal generated by a different method based on the search space where the PDCCH is detected and the RNTI scrambled to the CRC.

  The condition A includes receiving (detecting and decoding) a predetermined DCI format (hereinafter referred to as a first DCI format). Here, the first DCI format is defined in advance by specifications or the like and can be known information between the base station and the terminal. For example, the first DCI format includes DCI format 0. Here, DCI format 0 is transmitted by PDCCH in CSS and / or USS.

  That is, when the terminal receives the first DCI format, the terminal transmits the first reference signal generated using the first parameter. In addition, when the terminal receives the first DCI format, the terminal transmits a second reference signal generated using the first parameter. Further, when the terminal receives the first DCI format, the terminal transmits an uplink signal generated using the first parameter on the PUCCH.

  In addition, when transmitting the first DCI format, the base station receives the first reference signal generated using the first parameter. Further, when the base station transmits the first DCI format, the base station receives the second reference signal generated using the first parameter. In addition, when the base station transmits the first DCI format, the base station receives the uplink signal generated using the first parameter on the PUCCH.

That is, when the terminal receives the first DCI format, the terminal transmits the first reference signal generated using the N _ID ^cell . In addition, when the terminal receives the first DCI format, the terminal transmits a second reference signal generated using the N _ID ^cell . Further, when the terminal receives the first DCI format, the terminal transmits an uplink signal generated using the N _ID ^cell by PUCCH. The terminal, when receiving the first DCI format, transmits the first reference signal generated using the parameter delta _ss.

  The condition B includes reception (detection) of a DCI format other than the predetermined DCI format (hereinafter referred to as a second DCI format). For example, the DCI format 4 is included in the second DCI format. Here, the DCI format 4 is transmitted only by PDCCH in USS.

  That is, when the terminal receives the second DCI format, the terminal transmits the first reference signal generated using the second parameter. In addition, when the terminal receives the second DCI format, the terminal transmits a second reference signal generated using the second parameter. Further, when the terminal receives the second DCI format, the terminal transmits an uplink signal generated using the second parameter on the PUCCH.

  In addition, when the base station transmits the second DCI format, the base station receives the first reference signal generated using the second parameter. Further, when the second DCI format is transmitted, the base station receives the second reference signal generated using the second parameter. In addition, when the second DCI format is transmitted, the base station receives an uplink signal generated using the second parameter on the PUCCH.

  That is, when the terminal receives the second DCI format, the terminal transmits the first reference signal generated using the parameter “X”. Further, when receiving the second DCI format, the terminal transmits the first reference signal generated using the parameter “Y”. When the terminal receives the second DCI format, the terminal transmits the first reference signal generated using the parameter “Z”.

  Further, when the terminal receives the second DCI format, the terminal transmits the second reference signal generated using the parameter “X”. Further, when the terminal receives the second DCI format, the terminal transmits an uplink signal generated using the parameter “X” on the PUCCH. Further, when the terminal receives the second DCI format, the terminal transmits an uplink signal generated using the parameter “K” on the PUCCH.

  Here, downlink control information (for example, a reference sequence index, a reference sequence index related to PUCCH) for indicating a parameter is included in the second DCI format and transmitted.

  That is, the terminal transmits a first reference signal generated by a different method (using different parameters) to the base station based on the received DCI format. Further, the terminal transmits a second reference signal generated by a different method based on the received DCI format to the base station. Further, the terminal performs transmission on the PUCCH generated by a different method based on the received DCI format.

  That is, the terminal is generated in a different way (using different parameters) based on the DCI format, the search space in which the PDCCH was detected, the RNTI scrambled in the CRC, and the downlink control information to indicate the parameters. The first reference signal is transmitted to the base station.

  In addition, the terminal bases the second reference signal generated by a different method on the basis of the DCI format, the search space in which the PDCCH is detected, the RNTI scrambled in the CRC, and the downlink control information for indicating the parameter. Send to the station.

  In addition, the terminal uses the DCI format, the search space in which the PDCCH is detected, the RNTI scrambled to the CRC, and the downlink control information for indicating the parameters to generate uplink signals generated using different methods. Send with.

  In addition, the condition A includes initial transmission of a transport block (UL-SCH, uplink transport block) on the PUSCH scheduled by the random access response grant.

  That is, the terminal transmits the first reference signal generated using the first parameter when initially transmitting the transport block on the PUSCH scheduled by the random access response grant. In addition, when initially transmitting a transport block using PUSCH scheduled by a random access response grant, the terminal transmits a second reference signal generated using the first parameter.

  In addition, the terminal identifies the condition and generates the first reference signal based on the third parameter (generates a first reference signal sequence), or generates the first reference signal based on the fourth parameter. Can be generated or switched. That is, when the condition is A, the terminal generates the first reference signal based on the third parameter. Further, when the condition is B, the terminal generates a first reference signal based on the fourth parameter. Here, the condition A and the condition B are as described above.

  Here, the third parameter is a parameter set specifically for the cell. For example, the third parameter is specified using SIB2. For example, the third parameter includes information regarding validity or invalidity of sequence group hopping. Further, the third parameter includes information related to validity / invalidity of sequence hopping.

  The fourth parameter is a parameter set uniquely for the terminal. For example, the fourth parameter is indicated using the DCI format. In addition, the fourth parameter may be set using a dedicated signal. For example, the fourth parameter includes a setting related to validity / invalidity of sequence group hopping. In addition, the fourth parameter includes information related to validity or invalidity of sequence hopping. That is, the fourth parameter includes the parameter “M” described above.

  For example, when the condition is A, the terminal generates the first reference signal by enabling or disabling sequence group hopping based on the third parameter (the value of the third parameter). That is, when the condition is A, the terminal determines whether to hop the group of the first reference signal sequence for each slot based on the third parameter.

  Further, when the condition is A, the terminal enables or disables sequence hopping based on the third parameter (the value of the third parameter) and generates the first reference signal. That is, when the condition is A, the terminal determines whether to hop the first reference signal sequence for each slot in the group based on the third parameter.

  Further, when the condition is B, the terminal enables or disables the sequence group hopping based on the fourth parameter (the value of the fourth parameter) and generates the first reference signal. That is, when the condition is B, the terminal determines whether to hop the group of the first reference signal sequence for each slot based on the fourth parameter.

  Further, when the condition is B, the terminal enables or disables sequence hopping based on the fourth parameter (the value of the fourth parameter) and generates the first reference signal. That is, when the condition is B, the terminal determines whether to hop the first reference signal sequence for each slot in the group based on the fourth parameter.

  Further, the base station identifies the condition and assumes that the first reference signal is generated based on the third parameter (generates the first reference signal sequence), or based on the fourth parameter. It is possible to switch whether to assume that one reference signal is generated. That is, when the condition is A, the base station assumes that the first reference signal is generated based on the third parameter. Further, when the condition is B, the base station assumes that the first reference signal is generated based on the fourth parameter. Here, the condition A and the condition B are as described above.

  For example, when the condition is A, the base station receives the first reference signal by enabling or disabling sequence group hopping based on the third parameter (the value of the third parameter). When the condition is A, the base station receives the first reference signal with the sequence hopping enabled or disabled based on the third parameter (the value of the third parameter).

  Further, when the condition is B, the base station receives the first reference signal by enabling or disabling sequence group hopping based on the fourth parameter (the value of the fourth parameter). When the condition is B, the base station receives the first reference signal by enabling or disabling sequence hopping based on the fourth parameter (the value of the fourth parameter).

  By the method as described above, for example, the reference signal can be transmitted and received by switching the sequence more flexibly. Further, the reference signal can be transmitted and received by switching the sequence more dynamically by the method as described above.

  For example, the reference signal can be transmitted and received using the condition A during a period in which the base station and the terminal are performing settings in the RRC layer. That is, in the period when the setting in the RRC layer is unclear (the period in which the setting is inconsistent between the base station and the terminal), the reference signal is transmitted using the condition A. You can send and receive.

  Here, as described above, in the case of condition A, the terminal generates a reference signal using the cell-specific parameter. That is, it is possible to continue communication even during a period in which the base station and the terminal are performing settings in the RRC layer, and communication using radio resources efficiently can be performed.

  Also, by the method as described above, for example, it is possible to switch the sequence more flexibly and transmit / receive uplink signals. Also, uplink signals can be transmitted and received by switching the sequences more dynamically by the method as described above.

  For example, an uplink signal can be transmitted and received using the condition A during a period in which the base station and the terminal are performing settings in the RRC layer. That is, in the period when the setting is ambiguous (unclear), which occurs when the setting in the RRC layer is performed (the period in which the setting is inconsistent between the base station and the terminal), the uplink signal using the condition A Can be sent and received.

  Here, as described above, in the case of the condition A, the terminal generates an uplink signal using a cell-specific parameter. That is, it is possible to continue communication even during a period in which the base station and the terminal are performing settings in the RRC layer, and communication using radio resources efficiently can be performed.

  The program that operates in the primary base station, the secondary base station, and the terminal related to the present invention is a program (a program that causes a computer to function) that controls the CPU and the like so as to realize the functions of the above-described embodiments related to the present invention. Information handled by these devices is temporarily stored in the RAM at the time of processing, then stored in various ROMs and HDDs, read out by the CPU, and corrected and written as necessary. As a recording medium for storing the program, a semiconductor medium (for example, ROM, nonvolatile memory card, etc.), an optical recording medium (for example, DVD, MO, MD, CD, BD, etc.), a magnetic recording medium (for example, magnetic tape, Any of a flexible disk etc. may be sufficient. In addition, by executing the loaded program, not only the functions of the above-described embodiment are realized, but also based on the instructions of the program, the processing is performed in cooperation with the operating system or other application programs. The functions of the invention may be realized.

  In the case of distribution in the market, the program can be stored and distributed in a portable recording medium, or transferred to a server computer connected via a network such as the Internet. In this case, the storage device of the server computer is also included in the present invention. Moreover, you may implement | achieve part or all of the primary base station in the embodiment as mentioned above, the secondary base station, and the terminal as LSI which is typically an integrated circuit. Here, each functional block of the primary base station, the secondary base station, and the terminal may be individually chipped, or a part or all of them may be integrated into a chip. Further, the method of circuit integration is not limited to LSI's, and implementation using dedicated circuitry or general purpose processors is also possible. In addition, when an integrated circuit technology that replaces LSI appears due to progress in semiconductor technology, an integrated circuit based on the technology can also be used.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like without departing from the gist of the present invention. The present invention can be modified in various ways within the scope of the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments are also included in the technical scope of the present invention. It is. Moreover, it is the element described in each said embodiment, and the structure which substituted the element which has the same effect is also contained.

  The present invention is suitable for mobile station apparatuses, base station apparatuses, communication methods, wireless communication systems, and integrated circuits.

DESCRIPTION OF SYMBOLS 100 Base station 101 Data control part 102 Transmission data modulation part 103 Radio part 104 Scheduling part 105 Channel estimation part 106 Reception data demodulation part 107 Data extraction part 108 Upper layer 109 Antenna 200 Terminal 201 Data control part 202 Transmission data modulation part 203 Radio part 204 Scheduling unit 205 Channel estimation unit 206 Received data demodulation unit 207 Data extraction unit 208 Upper layer 209 Antenna 301 Primary base station 302 Secondary base station 303, 304 Terminals 305, 306, 307, 308 Uplink

Claims (12)

  A demodulating reference signal related to the transmission of the physical uplink shared channel, the demodulating reference signal sequence is provided with a reference sequence number, and includes a transmitting unit that transmits the demodulating reference signal to a base station device,
  The reference sequence number is given using a first parameter;
  When the value of the first information is set by an upper layer and the transmission of the physical uplink shared channel corresponds to downlink control information to which CRC parity bits scrambled by C-RNTI are added, The value of the first parameter is given using the value of the first information,
  If the value of the first information is not set by the upper layer, the value of the first parameter is given using a physical layer cell identity;
  When the transmission of the physical uplink shared channel corresponds to a random access response grant, the value of the first parameter is given using the physical layer cell identity.
  Terminal device.   The terminal apparatus according to claim 1, wherein transmission of the physical uplink shared channel corresponding to the random access response grant is transmission of a message 3 in a random access procedure.   The value of the first parameter is given using the physical layer cell identity when transmission of the physical uplink shared channel corresponds to retransmission of a transport block in a random access procedure. The terminal device described in 1.   The terminal apparatus according to claim 3, wherein retransmission of the transport block in the random access procedure is instructed using downlink control information to which CRC parity bits scrambled by Temporary C-RNTI are added.   A demodulating reference signal related to transmission of the physical uplink shared channel, the demodulating reference signal sequence is provided with a receiving unit that receives the demodulating reference signal given by using a standard sequence number from a terminal device;
  The reference sequence number is given using a first parameter;
  When the value of the first information is set by an upper layer and the transmission of the physical uplink shared channel corresponds to downlink control information to which CRC parity bits scrambled by C-RNTI are added, The value of the first parameter is given using the value of the first information,
  If the value of the first information is not set by the upper layer, the value of the first parameter is given using a physical layer cell identity;
  When the transmission of the physical uplink shared channel corresponds to a random access response grant, the value of the first parameter is given using the physical layer cell identity.
  Base station device.   The base station apparatus according to claim 5, wherein transmission of the physical uplink shared channel corresponding to the random access response grant is transmission of a message 3 in a random access procedure.   6. The value of the first parameter is given using the physical layer cell identity if the transmission of the physical uplink shared channel corresponds to a retransmission of a transport block in a random access procedure. The base station apparatus as described in.   The base station apparatus according to claim 7, wherein retransmission of the transport block in the random access procedure is instructed using downlink control information to which CRC parity bits scrambled by Temporary C-RNTI are added.   A communication method in a terminal device,
  A first step of transmitting a demodulation reference signal related to transmission of a physical uplink shared channel, wherein the demodulation reference signal sequence is given using a reference sequence number to a base station apparatus; Have
  The reference sequence number is given using a first parameter;
  When the value of the first information is set by an upper layer and the transmission of the physical uplink shared channel corresponds to downlink control information to which CRC parity bits scrambled by C-RNTI are added, The value of the first parameter is given using the value of the first information,
  If the value of the first information is not set by the upper layer, the value of the first parameter is given using a physical layer cell identity;
  When the transmission of the physical uplink shared channel corresponds to a random access response grant, the value of the first parameter is given using the physical layer cell identity.
  Communication method.   A communication method in a base station apparatus,
  A demodulating reference signal related to transmission of the physical uplink shared channel, the demodulating reference signal sequence being received using a reference sequence number, and receiving a demodulating reference signal from a terminal device; And
  The reference sequence number is given using a first parameter;
  When the value of the first information is set by an upper layer and the transmission of the physical uplink shared channel corresponds to downlink control information to which CRC parity bits scrambled by C-RNTI are added, The value of the first parameter is given using the value of the first information,
  If the value of the first information is not set by the upper layer, the value of the first parameter is given using a physical layer cell identity;
  When the transmission of the physical uplink shared channel corresponds to a random access response grant, the value of the first parameter is given using the physical layer cell identity.
  Communication method.   An integrated circuit that can be mounted on a terminal device, the terminal device
  A first step of transmitting to a base station apparatus a demodulation reference signal related to transmission of a physical uplink shared channel, wherein the demodulation reference signal sequence is given by using a reference sequence number.
  And execute
  The reference sequence number is given using a first parameter;
  When the value of the first information is set by an upper layer and the transmission of the physical uplink shared channel corresponds to downlink control information to which CRC parity bits scrambled by C-RNTI are added, The value of the first parameter is given using the value of the first information,
  If the value of the first information is not set by the upper layer, the value of the first parameter is given using a physical layer cell identity;
  When the transmission of the physical uplink shared channel corresponds to a random access response grant, the value of the first parameter is given using the physical layer cell identity.
  Integrated circuit.   An integrated circuit that can be mounted on a base station device, the base station device,
  A first step of receiving, from a terminal device, a demodulation reference signal related to transmission of a physical uplink shared channel, wherein the demodulation reference signal sequence is given by using a reference sequence number as a demodulation reference signal sequence
  And execute
  The reference sequence number is given using a first parameter;
  When the value of the first information is set by an upper layer and the transmission of the physical uplink shared channel corresponds to downlink control information to which CRC parity bits scrambled by C-RNTI are added, The value of the first parameter is given using the value of the first information,
  If the value of the first information is not set by the upper layer, the value of the first parameter is given using a physical layer cell identity;
  When the transmission of the physical uplink shared channel corresponds to a random access response grant, the value of the first parameter is given using the physical layer cell identity.
  Integrated circuit.