WO2013111843A1 - Mobile station device, base station device, and radio communication system - Google Patents

Abstract

Provided are a mobile station device, a base station device, and a radio communication system, wherein the mobile station device that supports machine type communication can efficiently perform communication. A mobile station device that communicates with a base station device and supports machine type communication monitors a physical downlink control channel in a common search space disposed in the middle of a downlink band in the base station device, and the common search space is disposed in a predefined number of resource blocks on the basis of a downlink bandwidth supported by the mobile station device.

Description

Mobile station apparatus, base station apparatus, and radio communication system

The present invention relates to a mobile station device, a base station device, and a radio communication system.

The third generation partnership project (3rd Generation Generation Partnership Project) is the evolution of wireless access methods and wireless networks for cellular mobile communications (hereinafter referred to as “Long Term Evolution (LTE)” or “Evolved Universal Terrestrial Radio Access: EUTRA”). : 3GPP). In LTE, an orthogonal frequency division multiplexing (多重 OFDM) method is used as a downlink communication method from a base station device to a mobile station device. Further, as an uplink communication method from the mobile station device to the base station device, an SC-FDMA (Single-Carrier Frequency Division Multiple Access) method is used. Here, in LTE, a base station apparatus is also called eNodeB (evolvedvolveNodeB), and a mobile station apparatus is also called UE (User Equipment). LTE is a cellular communication system in which a plurality of areas covered by a base station apparatus are arranged in a cell shape.

In LTE, the base station apparatus transmits a synchronization signal (Synchronization signal: SS) and a physical broadcast channel (Physical Broadcast Channel: PBCH) using 72 subcarriers in the center of the system band. In addition, the mobile station apparatus performs cell search (initial cell search, standby cell search and in-communication cell search) using the synchronization signal, and performs carrier frequency offset synchronization, OFDM symbol timing synchronization, radio frame timing synchronization, and physical layer cell identifier. (Physical-layer Cell Identity: PCI) is acquired. Further, after the cell search, the mobile station apparatus acquires a master information block (Master information block: MIB) using a physical broadcast channel. Here, the master information block includes information indicating the downlink system bandwidth of the cell, information indicating a system frame (radio frame) number (System Frame Number: SFN), and the like.

Further, after receiving the PBCH, the mobile station apparatus acquires a plurality of system information blocks (System information block: SIB) using a physical downlink shared channel (Physical Downlink Shared Channel: PDSCH). Here, MIB and SIB are system information. The SIB includes radio resource setting information common to a plurality of mobile station apparatuses. Here, the base station apparatus allocates a part of the downlink band of the cell to the PDSCH. Further, the base station apparatus transmits downlink control information (Downlink Control Information: DCI) used for scheduling of a single PDSCH using a single physical downlink control channel (Physical Downlink Control Channel: PDCCH). In addition, the base station apparatus transmits downlink control information used for scheduling of PDSCH for transmitting SIB using PDCCH in a common search region (Common Search Space: CSS). Here, CSS is used for transmission of PDCCH common to all mobile station apparatuses, and all mobile station apparatuses monitor (monitor) PDCCH in CSS.

Furthermore, the mobile station apparatus sets a physical random access channel (Physical Random Access Channel: PRACH) based on the radio resource setting information included in the SIB. In addition, after setting the PRACH, the mobile station apparatus starts a random access procedure and adjusts uplink transmission timing. Further, after adjusting the uplink transmission timing, the mobile station apparatus transmits a connection request message to the base station apparatus, and starts an initial connection establishment procedure.

Here, in LTE, a technology in which a mobile station apparatus and a base station apparatus communicate using a plurality of cells (component carriers) having the same channel structure (cell aggregation: cell-aggregation, carrier aggregation: also called carrier-aggregation) Is used. For example, in communication using cell aggregation, a mobile station apparatus and a base station apparatus can simultaneously transmit and receive on a plurality of physical channels using a plurality of cells. Further, for example, after the mobile station apparatus and the base station apparatus establish initial connection in one cell, a cell used by the base station apparatus for communication with the mobile station apparatus can be added.

On the other hand, in the study of the LTE-Advanced extended standard (LTE Release 11), Study Type Item for reducing the cost of machine type communication (Machine Type Communication: MTC) or machine-to-machine communication (Machine Type Communication: M2M) mobile stations is proposed. (Non-Patent Document 1). Hereinafter, the MTC / M2M mobile station apparatus or the MTC / M2M communication device is also referred to as MTCUE (Machine Type Communication User Equipment). In other words, in order to realize a low-cost MTCUE while having backward compatibility with the LTE standard (LTE Release 8, 9) and LTE-Advanced standard (LTE 対 応 Release 10) compatible systems, Cost reduction methods such as reduction in the number of antenna ports / RF chains, reduction in transmission / reception data transfer rate, adoption of half-duplex frequency division multiplexing (Half-duplex Frequency Division Duplex) method, transmission power reduction, and extension of intermittent reception interval Proposed.

As described above, in order to realize a low-cost MTCUE, it has been proposed that the maximum transmission / reception frequency bandwidth of the MTCUE is limited to a frequency bandwidth narrower than 20 MHz, for example, 1.4 MHz. However, the base station apparatus transmission / reception method, mobile station apparatus transmission / reception method, and communication protocol are compatible with conventional LTE standard (LTE Release 8 and 9) and LTE-Advanced standard (LTE Release 10) compatible systems. No specific implementation method is presented.

(1) In order to achieve the above object, the present invention has taken the following measures. That is, a mobile station device that supports machine type communication that communicates with a base station device, and monitors a physical downlink control channel in a common search region arranged in the center of the downlink band in the base station device, The common search area is arranged in a predetermined number of resource blocks based on a downlink bandwidth supported by the mobile station apparatus.

(2) Further, the mobile station apparatus is characterized by monitoring downlink control information accompanied by a random access identifier in the physical downlink control channel.

(3) Further, the mobile station apparatus is characterized by monitoring downlink control information accompanied with a temporary radio network identifier in the physical downlink control channel.

(4) Further, the mobile station apparatus is characterized by monitoring paging information in the physical downlink control channel.

(5) In addition, a base station apparatus that communicates with a mobile station apparatus that supports machine type communication, and a physical downlink control channel is arranged in a common search region arranged in the center of the downlink band in the base station apparatus The common search area is arranged in a predetermined number of resource blocks based on a downlink bandwidth supported by the mobile station apparatus.

(6) Further, the base station apparatus transmits downlink control information accompanied by a random access identifier to the mobile station apparatus in the physical downlink control channel.

(7) Further, the base station apparatus transmits downlink control information accompanied by a random access identifier to the mobile station apparatus in the physical downlink control channel.

(8) Further, the base station apparatus transmits paging information to the mobile station apparatus in the physical downlink control channel.

(9) A wireless communication system in which a base station apparatus and a mobile station apparatus corresponding to machine type communication communicate with each other, wherein the base station apparatus is located in the center of a downlink band in the base station apparatus. In the area, a physical downlink control channel is arranged, the mobile station apparatus monitors the physical downlink control channel, and the common search area is preliminarily determined based on a downlink bandwidth supported by the mobile station apparatus. It is characterized in that it is arranged in a prescribed number of resource blocks.

(10) Further, the mobile station apparatus communicates with the base station apparatus, and a resource defined exclusively for the mobile station apparatus corresponding to machine type communication is allocated by the base station apparatus, and the resource is used. And performing a random access procedure.

(11) The resource includes scheduling information related to the random access of the mobile station apparatus corresponding to the machine type communication or sequence information related to the random access of the mobile station apparatus corresponding to the machine type communication. Yes.

(12) Further, the resource is allocated to the mobile station apparatus by the base station apparatus using a system information block.

(13) A base station apparatus that communicates with a mobile station apparatus, wherein a resource defined exclusively for a mobile station apparatus that supports machine type communication is allocated to the mobile station apparatus, and the resource is used It is characterized by executing a random access procedure.

(14) The resource includes scheduling information related to the random access of the mobile station apparatus corresponding to the machine type communication or sequence information related to the random access of the mobile station apparatus corresponding to the machine type communication. Yes.

(15) Further, the base station apparatus is characterized in that the resource is allocated to the mobile station apparatus using a system information block.

(16) A wireless communication system in which a base station device and a mobile station device communicate with each other, wherein the base station device assigns a resource defined exclusively for a mobile station device corresponding to machine type communication to the mobile station. The mobile station apparatus performs a random access procedure using the resource.

(17) In addition, the mobile station device supports machine type communication that communicates with the base station device, and uses a physical uplink control channel arranged only at one end of the uplink band in the base station device, Link control information is transmitted to the base station apparatus.

(18) A base station apparatus that communicates with a mobile station apparatus that supports machine type communication, and a physical uplink control channel that is arranged only at one end of an uplink band in the base station apparatus is transmitted to the mobile station apparatus. It is characterized by assigning.

(19) A radio communication system in which a base station apparatus and a mobile station apparatus corresponding to machine type communication communicate with each other, wherein the base station apparatus is a physical station arranged only at one end of an uplink band in the base station apparatus. An uplink control channel is allocated to the mobile station apparatus, and the mobile station apparatus transmits uplink control information to the base station apparatus using the physical uplink control channel.

According to the present invention, a mobile station apparatus compatible with machine type communication can efficiently communicate.

It is a conceptual diagram of the radio | wireless communications system in connection with the 1st Embodiment of this invention. It is a figure which shows an example of the structure of the downlink radio frame concerning the 1st Embodiment of this invention, and the mapping of the physical downlink channel corresponding to UE1. It is a figure which shows an example of the mapping of the physical downlink channel corresponding to MTCUE1 in connection with the 1st Embodiment of this invention. It is a figure which shows another example of the mapping of the physical downlink channel corresponding to MTCUE1 in connection with the 1st Embodiment of this invention. It is a figure which shows another example of the mapping of the physical downlink channel corresponding to MTCUE1 in connection with the 1st Embodiment of this invention. It is a figure which shows an example of the search space of the mobile station apparatus in connection with the 1st Embodiment of this invention. It is a figure which shows an example of a structure of the search space in the resource area | region of PDCCH in connection with the 1st Embodiment of this invention, or the resource area | region of MTC-PDCCH (4). It is a figure which shows an example of the mapping of the SIB resource in connection with the 1st Embodiment of this invention. It is a figure which shows an example of the structure of the uplink radio frame in connection with the 1st Embodiment of this invention, and the mapping of the physical uplink channel corresponding to UE1. It is a figure which shows an example of the mapping of the physical uplink channel corresponding to MTCUE1 in connection with the 1st Embodiment of this invention. It is a figure which shows an example of the mapping of the resource for PRACH in connection with the 1st Embodiment of this invention. It is a figure which shows an example of the system information acquisition procedure of the mobile station apparatus in connection with the 1st Embodiment of this invention. It is a figure which shows the example of the RACH sequence group in connection with the 1st Embodiment of this invention. It is a figure which shows the example of the RACH sequence group in connection with the 1st Embodiment of this invention. It is a figure which shows an example of a random access procedure in connection with the 1st Embodiment of this invention. It is a figure which shows an example of the transmission procedure of paging in connection with the 1st Embodiment of this invention. It is a figure which shows the structure of the base station apparatus in connection with the 1st Embodiment of this invention. It is a figure which shows the structure of MTCUE1 in connection with the 1st Embodiment of this invention.

First embodiment for carrying out the invention

Hereinafter, the first embodiment of the present invention will be described in detail with reference to the drawings.

A physical channel of the wireless communication system according to the first embodiment of the present invention will be described. FIG. 1 is a conceptual diagram of a wireless communication system according to the first embodiment of the present invention. In FIG. 1, the wireless communication system includes a low-cost MTC mobile station apparatus (1A to 1C) compatible with the LTE-Advanced extended standard (LTE Release 11) related to the present invention, and the conventional LTE standard (LTE Release 8,9). And a mobile station device (2A to 2C) compliant with the LTE-Advanced standard (Release 10), and a base station device (3). Hereinafter, the low-cost MTC mobile station apparatus (1A to 1C) corresponding to the LTE-Advanced extended standard (LTE Release 11) is referred to as MTCUE1, the conventional LTE standard (LTE Release 8,9), and the LTE-Advanced standard (LTE Release 10). ) The corresponding mobile station devices (2A to 2C) are referred to as UE1. Including MTCUE1 and UE1, these are collectively referred to as mobile station apparatuses. Base station apparatuses (3) corresponding to UE1 and MTCUE1 are collectively referred to as base station apparatuses.

Here, MTCUE1 (also referred to as an MTC device or MTC terminal) includes user equipment provided for machine type communication (communication between machines). For example, MTCUE1 can communicate with an access network comprising multiple cells with different characteristics (eg, eNodeBs, home 、 eNodeBs, e-UTRA Relays).

FIG. 1 shows a downlink reference signal (Downlink Reference Signal: DLRS), a synchronization signal (Synchronization signal: SS), a physical broadcast channel (Physical Broadcast Channel: PBCH), in downlink radio communication from the base station apparatus to the UE1. Physical Downlink Control Channel (Physical Downlink Control Channel: PDCCH), Physical Downlink Shared Channel (Physical Downlink Shared Channel: PDSCH), Physical Control Format Indicator Channel (Physical Control Format Indicator Channel: PCFICH) and Physical HARQ Indicator Channel (Physical Hybrid) ARQ Indicator Channel: PHICH) is used.

FIG. 1 also shows DLRS, SS, PBCH shared with UE1, physical downlink control channel (4) (MTC-PDCCH) compatible with MTCUE1, and MTCUE1 in downlink radio communication from the base station apparatus to MTCUE1. Physical downlink shared channel (MTC-PDSCH), MTCUE1-compatible physical control format indicator channel (MTC-PCFICH), and MTCUE1-compatible physical HARQ indicator channel (MTC-PHICH).

In addition, FIG. 1 illustrates uplink reference signals (Uplink Reference Signal: ULS), physical uplink control channel (Physical Uplink Control Channel: PUCCH), and physical uplink shared in uplink radio communication from UE1 to the base station apparatus. It indicates that a channel (Physical Uplink Shared Channel: PUSCH) and a physical random access channel (Physical Random Access Channel: PRACH) are used.

FIG. 1 shows an uplink reference signal (MTC-Uplink-Reference Signal: MTC-ULRS) compatible with MTCUE1 and a physical uplink control channel (9) compatible with MTCUE1 in uplink radio communication from MTCUE1 to the base station apparatus. MTC-Physical-Uplink-Control Channel: MTC-PUCCH, MTCUE1-compatible physical uplink shared channel (MTC-Physical-Uplink Shared Channel: MTC-PUSCH) and MTCUE1-compatible physical random access channel (10) (MTC-Physical-Random Access-Channel: MTC- PRACH) is used.

Here, SS is used for UE to synchronize downlink frequency domain and time domain. The downlink reference signal is used for the UE to synchronize the frequency domain and the time domain of the downlink, the UE is used to measure the reception quality of the downlink, or the UE uses the PDSCH or PDCCH propagation path. Used to make corrections.

The PBCH is a physical channel used for broadcasting a master information block (Master Information Block: MIB) that is system information commonly used by UEs in a cell. For example, PBCH is transmitted at intervals of 40 ms. Here, the timing at intervals of 40 ms is blind-detected at the UE. The PBCH is retransmitted at 10 ms intervals. The MIB includes essential physical layer information for receiving other system information such as a system bandwidth and a radio frame number (System Frame: SFN).

The PDCCH also includes downlink control information (Downlink Control Information: DCI) such as downlink assignment (also referred to as “Downlink Grant: DG” or “Downlink Grant: DG”) and uplink grant (Uplink Grant: UG). ) Is the physical channel used to transmit. For example, the downlink assignment includes information on modulation scheme and coding rate for PDSCH (Modulation & Coding Scheme: MCS), information indicating radio resource allocation, TPC command (Transmission Power Control Command) for PUCCH, and the like. . Further, the uplink grant includes information on modulation scheme and coding rate for PUSCH, information indicating radio resource allocation, TPC command for PUSCH, and the like.

Here, a plurality of formats are defined in the downlink control information transmitted on the PDCCH. The format of the downlink control information is called a DCI format (DCIDformat). For example, DCI format 0 is used for scheduling of a PUSCH of a single antenna port transmission scheme in a single cell. Further, the DCI format 4 is used for PUSCH scheduling of a multi-antenna port transmission scheme in a single cell. The DCI format 1A is used for scheduling a PDSCH in a single antenna port transmission scheme or transmission diversity transmission scheme in a single cell. The DCI format 2 is used for scheduling of the PDSCH of the multi-antenna port transmission method in a single cell. That is, DCI format 0 and DCI format 4 are uplink grants. DCI format 1A and DCI format 2 are downlink assignments.

PDSCH is a physical channel used for transmitting paging information (Paging Channel: PCH), SIB information (Broadcast Channel: BCH), and downlink data (Downlink Shared Channel: DL-SCH). Here, the SIB information includes radio resource setting information common to a plurality of UEs.

PCFICH is a physical channel used for transmitting information indicating a region (OFDM symbol) in which PDCCH is arranged. PHICH is a physical channel used for transmitting a HARQ indicator (response information) indicating success or failure of decoding of uplink data received by the base station apparatus. For example, when the base station apparatus succeeds in decoding the uplink data included in the PUSCH, the HARQ indicator for the uplink data indicates ACK (Acknowledgement), and the base station apparatus decodes the uplink data included in the PUSCH. In case of failure, the HARQ indicator for the uplink data indicates NACK (Negative Acknowledgment). A single PHICH transmits a HARQ indicator for a single uplink data. HARQ indicators for a plurality of uplink data included in the same PUSCH are transmitted using a plurality of PHICHs.

Furthermore, MTC-PDCCH (4) is a PDCCH corresponding to MTCUE1, and is a physical channel used for transmitting downlink control information (DCI) for MTCUE1.

Also, MTC-PDSCH is a PDSCH corresponding to MTCUE1, and is a physical channel used for transmitting PCH, SIB information and DL-SCH to MTCUE1. MTC-PCFICH is a PCFICH compatible with MTCUE1, and is a physical channel used for transmitting information indicating an area (OFDM symbol) in which MTC-PDCCH (4) is arranged. MTC-PHICH is a PHICH corresponding to MTCUE1, and is a physical channel used for transmitting a HARQ indicator (response information) indicating success or failure of decoding of uplink data received by the base station apparatus.

Also, ULRS is used for the base station apparatus to synchronize the uplink time domain of UE1, the base station apparatus is used for measuring the uplink reception quality of UE1, or the base station apparatus It is a signal used to perform propagation channel correction for PUSCH and PUCCH. The ULRS includes a demodulation reference signal (Demodulation Reference Signal: DMRS) that is one of the ULRSs that are time-multiplexed with the PUSCH or the PUCCH, and one ULRS that is transmitted regardless of the PUSCH and the PUCCH. There is a sanding reference signal (Sounding Reference Signal: SRS).

Further, PUCCH is channel state information (Channel Information: CSI) indicating downlink channel quality, scheduling request (Scheduling Request: SR) indicating a request for radio resources of PUSCH, and decoding of downlink data received by UE1. It is a physical channel used for transmitting uplink control information (Uplink Control Information: UCI) that is information used for communication control, such as ACK / NACK indicating success or failure.

Also, PUSCH is a physical channel used for transmitting uplink data (Uplink Shared Channel: UL-SCH) and uplink control information. PRACH is a physical channel used for transmitting a random access preamble. The PRACH is mainly intended for the UE 1 to synchronize with the base station apparatus in the time domain, and in addition, an initial connection establishment (initial connection） establishment) procedure, a handover procedure, and a connection re-establishment (connection re-establishment) procedure. Used for uplink transmission synchronization (timing adjustment) and uplink radio resource allocation request.

The MTC-ULRS is used for the base station apparatus to synchronize the uplink time domain of the MTCUE1, the base station apparatus is used for measuring the reception quality of the uplink of the MTCUE1, This is a signal used by the apparatus for channel correction of MTC-PUSCH and MTC-PUCCH (9). The MTC-ULRS includes a demodulation reference signal (MTC-Demodulation-Reference-Signal: MTC-DMRS) for MTCUE data, which is one of the MTC-ULRSs that are time-multiplexed with the MTC-PUSCH or MTC-PUCCH (9) and transmitted. In addition, there is a MTC-UE Sanding Reference Signal (MTC-Sounding Reference-Signal: MTC-SRS), which is one of MTC-ULRS transmitted irrespective of MTC-PUSCH and MTC-PUCCH (9).

MTC-PUCCH (9) is channel state information (MTC Channel State: MTC-CSI) indicating downlink channel quality of MTCUE1, and a scheduling request (MTC Scheduling Request: indicating MTC-PUSCH radio resource request). MTC-SR), for transmitting uplink control information (MTC-Uplink-Control-Information: MTC-UCI) that is information used for communication control, such as ACK / NACK indicating success or failure of decoding of downlink data received by MTCUE1 Is a physical channel used for

The MTC-PUSCH is a physical channel used for transmitting MTCUE uplink data (MTC-Uplink-Shared Channel: MTC-UL-SCH) and uplink control information. MTC-PRACH (10) is a physical channel used for transmitting the random access preamble for MTCUE. MTC-PRACH (10) is mainly intended for MTCUE1 to synchronize with the base station apparatus in the time domain. Besides, initial connection establishment (initial 確立 connection establishment) procedure, handover procedure, connection reestablishment (connection re- establishment) procedure, synchronization for uplink transmission (timing adjustment), and uplink radio resource allocation request.

FIG. 2 is a diagram illustrating an example of a configuration of a downlink radio frame according to the first embodiment of the present invention. As a time resource, a radio frame has a length of 10 ms and is composed of 10 subframes. The length of the subframe is 1 ms, and is composed of two slots. The slot length is 0.5 ms, and is composed of 7 OFDM symbols. As a frequency resource, the downlink system bandwidth is composed of a plurality of OFDM subcarriers. The frequency bandwidth of one subcarrier is 15 kHz, and the number of subcarriers depends on the downlink system bandwidth. A resource element, which is the minimum unit of radio resources, is composed of one subcarrier and one OFDM symbol. A resource element is identified using a subcarrier number and an OFDM symbol number.

Here, the resource block is used to express mapping of resource elements of a certain physical downlink channel. As resource blocks, virtual resource blocks and physical resource blocks are defined. A certain physical downlink channel is first mapped to a virtual resource block. Thereafter, the virtual resource block is mapped to the physical resource block. One physical resource block is defined by 7 consecutive OFDM symbols in the time domain and 12 consecutive subcarriers in the frequency domain. Therefore, one physical resource block is composed of (7 × 12) resource elements. One physical resource block corresponds to one slot in the time domain and corresponds to 180 kHz in the frequency domain. Physical resource blocks are numbered from 0 in the frequency domain.

(About physical downlink channel mapping)
Moreover, FIG. 2 is a figure which shows an example of the mapping of the physical downlink channel corresponding to UE1 in connection with the 1st Embodiment of this invention. The PCFICH is mapped to the 0th (first) OFDM symbol in the subframe. PCFICH is mapped to four resource element groups distributed in the frequency domain. A resource element group is composed of a plurality of continuous resource elements. The PHICH is mapped to the OFDM symbol of the 0th (first subframe) in the subframe. One PCFICH is mapped to three resource element groups distributed in the frequency domain. Also, the base station apparatus can code multiplex a plurality of PCFICHs on the same resource element.

Here, the PDCCH is mapped to OFDM symbols from No. 0, No. 0 and No. 1 or No. 0 to No. 2 in the subframe. In the 0th OFDM symbol, PDCCH is mapped avoiding resource elements to which PCFICH and PHICH are mapped. UE1 recognizes the OFDM symbol to which PDCCH is mapped based on the information received by PCFICH. Further, the base station apparatus can multiplex a plurality of PDCCHs in time and frequency.

Also, the PDSCH is mapped to an OFDM symbol to which no PDCCH in the subframe is mapped. The base station apparatus can frequency-multiplex, time-multiplex and / or spatially multiplex a plurality of PDSCHs.

Also, the SS is transmitted in the 0th and 5th subframes in each radio frame in the time domain. In the 0th and 5th subframes, the synchronization signal is transmitted using the 5th and 6th OFDM symbols in the first slot. In addition, the synchronization signal is transmitted in 72 subcarriers in the frequency domain symmetrically with respect to the center frequency f1 of the downlink system bandwidth of the cell.

Also, the PBCH is transmitted in the 0th subframe in each radio frame in the time domain. In the 0th subframe, the PBCH is transmitted using OFDM symbols from the 0th to the 3rd in the second slot. Also, PBCH is transmitted in 72 subcarriers in the center of the downlink system band of the cell in the frequency domain. In FIG. 2, the description of the downlink reference signal is omitted.

FIG. 3 is a diagram illustrating an example of physical downlink channel mapping corresponding to MTCUE1 according to the first embodiment of the present invention. In FIG. 3, the resource element corresponding to UE1 is shown centering on the center frequency f1 of the downlink system bandwidth (for example, 20 MHz), and the downlink system bandwidth corresponding to MTCUE1 (for example, 5 MHz) is the downlink corresponding to UE1. Within system bandwidth (eg 20 MHz). Note that the downlink system bandwidth corresponding to MTCUE1 (also referred to as downlink bandwidth) indicates the downlink system bandwidth supported by MTCUE1. Here, the center frequency of the downlink system bandwidth (for example, 5 MHz) corresponding to MTCUE1 is f1. That is, the downlink system bandwidth corresponding to MTCUE1 is narrower than the downlink system bandwidth (for example, 20 MHz) in the base station apparatus, and can have, for example, 1.4 MHz, 3 MHz, 5 MHz, 10 MHz, and 15 MHz. That is, for example, MTCUE1 can operate in the downlink system bandwidth corresponding to MTCUE1, such as 1.4 MHz, 3 MHz, 5 MHz, 10 MHz, and 15 MHz. That is, it can be considered that the downlink system bandwidth corresponding to MTCUE1 is more limited than that of the conventional UE1.

In FIG. 3, for example, SS, PBCH, and DLRS corresponding to MTCUE1 use resource elements within the downlink system bandwidth corresponding to MTCUE1 by using those corresponding to UE1.

Here, MTC-PCFICH is mapped to the OFDM symbol of No. 6 (last subframe) in the subframe. Also, MTC-PCFICH is mapped to four resource element groups distributed in the frequency domain. A resource element group is composed of a plurality of continuous resource elements. MTC-PHICH is mapped to the 6th OFDM symbol in the subframe. One MTC-PCFICH is mapped to three resource element groups distributed in the frequency domain. Also, the base station apparatus can code multiplex a plurality of MTC-PCFICHs on the same resource element.

Further, for example, the MTC-PDCCH (4) is the sixth MTC-PDCCH resource region (4A), the sixth and fifth MTC-PDCCH resource regions (4B), or the sixth to fourth in the subframe. Are mapped to OFDM symbols up to the MTC-PDCCH resource region (4C). Here, in the 6th OFDM symbol, MTC-PDCCH (4) is mapped avoiding the resource elements to which MTC-PCFICH and MTC-PHICH are mapped. Further, MTCUE1 recognizes the OFDM symbol (the start position of the OFDM symbol) to which MTC-PDCCH (4) is mapped based on the information received by MTC-PCFICH.

Also, MTC-PDSCH is mapped to an OFDM symbol to which MTC-PDCCH (4) in a subframe within the downlink system bandwidth corresponding to MTCUE1 is not mapped. The base station apparatus can frequency multiplex, time multiplex and / or spatially multiplex a plurality of MTC-PDSCHs. Here, since the resource region of MTC-PDSCH is the same as the resource region of PDSCH within the downlink system bandwidth corresponding to MTCUE1, MTC-PDSCH has the same meaning as PDSCH within the downlink system bandwidth compatible with MTCUE1. . In the base station apparatus, the mapping of the UE1 and MTCUE1 resources in the two resource areas has no collision and can be scheduled appropriately.

Similarly, FIGS. 4A and 4B are other diagrams showing an example of physical downlink channel mapping corresponding to MTCUE1. As shown in FIG. 4a, for example, the MTC-PDCCH (11) is an MTC-PDCCH resource region (11A to 11C) composed of a plurality of physical resource blocks in a subframe within the downlink system bandwidth corresponding to MTCUE1. ). MTC-PDCCH (11) is mapped avoiding resource elements to which MTC-PCFICH and MTC-PHICH are mapped. MTCUE1 recognizes the size of the physical resource area to which MTC-PDCCH (11) is mapped, for example, the MTC-PDCCH area (11A to 11C) block shown in FIG. 4a, based on the information received by MTC-PCFICH .

Also, as shown in FIG. 4a, the MTC-PDCCH resource region (11A to 11C) is mapped to a plurality of physical resource blocks in the second slot. As an example, the MTC-PDCCH resource regions (11A to 11C) are mapped to 1, 2, and 3 physical resource blocks, respectively. The number of physical resource blocks is indicated by MTC-PCFICH information.

Also, MTC-PCFICH is mapped to the resource area (11A to 11C) of MTC-PDCCH. For example, it is mapped to the first OFDM symbol in the second slot. MTC-PCFICH is mapped to two resource element groups distributed in the frequency domain. A resource element group is composed of a plurality of continuous resource elements.

Also, MTC-PHICH is mapped to, for example, the second OFDM symbol in the second slot. One MTC-PHICH is mapped to two resource element groups distributed in the frequency domain. Also, the base station apparatus can code multiplex a plurality of MTC-PHICHs on the same resource element.

Also, MTC-PDSCH is mapped to an OFDM symbol to which MTC-PDCCH (4) in a subframe within the downlink system bandwidth corresponding to MTCUE1 is not mapped. The base station apparatus can frequency multiplex, time multiplex and / or spatially multiplex a plurality of MTC-PDSCHs. Here, since the MTC-PDSCH region is the same as the PDSCH region within the downlink system bandwidth corresponding to MTCUE1, MTC-PDSCH has the same meaning as the PDSCH within the downlink system bandwidth compatible with MTCUE1. In the base station apparatus, the UE1 and MTCUE1 resource mapping in the two regions does not collide and can be scheduled appropriately.

As shown in FIG. 4a, the resource region of MTC-PDCCH (11A-11C) has shown to have one or more physical resource blocks in the second slot, but as shown in FIG. 4b, It may have a first slot and / or a second slot on the time axis and one or more unit bandwidths (eg 6 subcarriers) on the frequency axis.

Also, as shown in FIG. 4a, the MTC-PDCCH resource regions (11A to 11C) are continuously mapped (localized) in units of physical resource blocks on the frequency axis, but as shown in FIG. 4b. The distributed mapping can be performed in units of physical resource blocks or a unit bandwidth (for example, 6 OFDM subcarriers).

Here, just as UE1 knows the position where the PCFICH is mapped in advance, MTCUE1 has one end of the downlink system band corresponding to MTCUE1 as shown in FIG. ), It is possible to know the position where MTC-PCFICH is mapped by previously identifying that it is mapped to the first OFDM symbol in the second slot.

Also, the mapping position of MTC-PCFICH is, as shown in FIG. 4b, from one end (for example, the high frequency end) of the downlink system band corresponding to MTCUE1 and / or from the beginning of the subframe (for example, the first subframe), It is possible to start from a position specified by a preset frequency offset and / or time offset. In addition, for example, these offsets are based on parameters specific to the base station (Cell Special) (for example, PCI) or parameters specific to the mobile station (UE Special) (for example, terminal manufacturing number, individual identification number, user number, etc.) Can be calculated.

(Search space for mobile station equipment)
FIG. 5 is a diagram illustrating an example of a search space of the mobile station apparatus according to the first embodiment of the present invention. As shown in FIG. 5, a common search space (Common Search Space: CSS) and a specific search space (UE specific Search Space: USS) of the mobile station apparatus are configured in the resource region of the UE 1 compatible PDCCH resource. That is, a CSS that is a common search space is defined (arranged and set) for UEs 1A to 1C that are a plurality of UEs 1. In addition, a USS that is a unique search space is defined for UE1A that is a specific UE1. Here, CSS and USS are a set of resources that the base station apparatus can use for PDCCH transmission.

Here, CSS is defined by a common resource for a plurality of UE1s. Moreover, USS is defined independently with respect to each of UE1. In the CSS, the base station apparatus transmits a DCI format intended for a plurality of UE1s and / or a DCI format intended for a specific UE1. For example, the DCI format for a plurality of UEs 1 is a DCI format used for SIB scheduling or a DCI format used for PRACH response scheduling. The base station apparatus transmits a DCI format intended for a specific UE 1 in USS.

In FIG. 5, UE1 monitors PDCCH in CSS (trying to decode PDCCH). Moreover, UE1 monitors PDCCH in USS. That is, UE1 monitors a set of PDCCH candidates addressed to itself. Here, monitoring means that UE1 attempts to decode each PDCCH in the set of PDCCH candidates according to all the DCI formats to be monitored (also referred to as blind decoding). Here, for example, RNTI (Radio Network Temporary Identifier) is used for transmission of downlink control information (transmission on PDCCH). Specifically, a CRC parity bit (also simply referred to as CRC) generated based on downlink control information (which may be a DCI format) is added to the downlink control information, and after the CRC parity bit is added, Scrambled with RNTI. For example, the CRC parity bit and C-RNTI are represented by 16 bits. The mobile station apparatus decodes downlink control information accompanied by CRC parity bits scrambled by RNTI. That is, the mobile station apparatus decodes the PDCCH accompanied by CRC parity bits scrambled by RNTI. Here, for example, RNTI includes RA-RNTI, Temporary C-RNTI, and C-RNTI.

In addition, the MTC-PDCCH (4) -compatible MTC-PDCCH (4) resource region includes an MTCUE1-compatible search space (5) (MTC Common Search Space: MTC-CSS) and an MTCUE1-compatible search space (6) (MTC UE specific). Search Space: MTC-USS). That is, MTC-CSS (5) that is a common search space is defined for MTCUE1A to 1C that are a plurality of MTCUE1s. Also, MTC-USS (6), which is a unique search space, is defined for MTCUE1A that is a specific MTCUE1. Here, MTC-CSS (5) and MTC-USS (6) are a set of resources that the base station apparatus can use for transmission of MTC-PDCCH (4). In FIG. 5, MTCUE1 monitors MTC-PDCCH (4) in MTC-CSS (5). MTCUE1 monitors MTC-PDCCH (4) in MTC-USS (6).

Here, MTC-CSS (5) is defined by a common resource for a plurality of MTCUE1s. Also, MTC-USS (6) is defined independently for each MTCUE1. In the MTC-CSS (5), the base station apparatus transmits a DCI format intended for a plurality of MTCUE1s and / or a DCI format intended for a specific MTCUE1. For example, the DCI format including a plurality of MTCUE1s includes a DCI format used for SIB scheduling or a DCI format used for MTC-PRACH (10) response scheduling. For example, the base station apparatus transmits a DCI format intended for a specific MTCUE1 in MTC-USS (6).

Here, as shown in FIG. 5, MTC-CSS (5) may be defined at the center of the downlink band (center of the downlink cell). For example, MTC-CSS (5) may be defined within a predetermined number of subcarriers (eg, within 72 subcarriers or within 300 subcarriers) in the center of the downlink band. For example, MTC-CSS (5) may be defined in a predetermined number of resource blocks in the center of the downlink band (for example, in 6 resource blocks or 25 resource blocks). Here, the predefined number of subcarriers in the center of the downlink band or the predefined number of resource blocks in the center of the downlink band are based on the downlink bandwidth supported by the MTCUE1. That is, for example, MTC-CSS (5) is defined in a part of the center of the downlink band. Further, for example, MTC-CSS (5) may be defined by a calculation formula used to specify a search space (search space position). For example, MTC-CSS (5) may be defined by setting the value of any one of a plurality of parameters included in the calculation formula to a fixed value (for example, 0). That is, how the MTC-CSS (5) is defined in the downlink band is defined in advance by specifications or the like, and can be known between the base station apparatus and the MTCUE1. By doing so, MTCUE1 can monitor MTC-PDCCH (4) in MTC-CSS (5) arranged in the center of the downlink band in the base station apparatus.

Also, MTC-CSS (5) may be defined in a resource area set by the base station apparatus. For example, the base station apparatus can set the resource region in which the MTC-CSS (5) is arranged for the mobile station apparatus using a higher layer signal. For example, MTCUE1 can monitor MTC-PDCCH (4) in MTC-CSS (5) defined in advance in the center of the downlink band at the time of initial connection. For example, MTCUE1 can monitor MTC-PDCCH (4) in MTC-CSS (5) set by the base station apparatus after the initial connection. Here, for example, MTCUE1 may monitor MTC-PDCCH (4) in MTC-CSS (5) defined in advance in the center of the downlink band after the initial connection.

Also, as shown in FIG. 5, MTC-USS (6) may be defined at the center of the downlink band (center of the downlink cell). For example, MTC-USS (6) may be defined within a predetermined number of subcarriers (eg, within 72 subcarriers or within 300 subcarriers) in the center of the downlink band. For example, MTC-USS (6) may be defined in a predetermined number of resource blocks in the center of the downlink band (for example, in 6 resource blocks or 25 resource blocks). That is, for example, MTC-USS (6) is defined in a part of the center of the downlink band. Also, for example, MTC-USS (6) may be defined by a calculation formula used to specify a search space (search space position).

Also, MTC-USS (6) may be defined in a resource area set by the base station apparatus. For example, the base station apparatus can set the resource region in which the MTC-CSS (5) is arranged for the mobile station apparatus using a higher layer signal. For example, during initial connection, MTCUE1 can monitor MTC-PDCCH (4) in MTC-USS (6) defined in advance in the center of the downlink band. For example, MTCUE1 can monitor MTC-PDCCH (4) in MTC-USS (6) set by the base station apparatus after the initial connection. Here, for example, MTCUE1 may monitor MTC-PDCCH (4) in MTC-USS (6) defined in advance in the center of the downlink band after the initial connection.

FIG. 6 is a diagram showing a configuration of a search space in the PDCCH resource area or the MTC-PDCCH (4) resource area according to the first embodiment of the present invention. In the PDCCH resource area or the MTC-PDCCH (4) resource area, aggregation level 4 CSS or MTC-CSS (5), aggregation level 8 CSS or MTC-CSS (5), and aggregation level 1 USS or MTC-USS (6) at aggregation level 2, USS or MTC-USS (6) at aggregation level 2, USS or MTC-USS (6) at aggregation level 4, USS or MTC-USS at aggregation level 8 (6 ) Is configured. CSS or MTC-CSS (5) is composed of control channel elements having a predetermined number.

That is, for example, MTC-CSS (5) and MTC-USS (6) may be defined in the resource area of MTC-PDCCH (4), respectively. Further, for example, the aggregation level (4, 8) in MTC-CSS (5) may be limited to a lower aggregation level than the aggregation level (1, 2, 4, 8) in MTC-USS (6). .

In FIG. 6, for example, an aggregation level 4 CSS or MTC-CSS (5) and an aggregation level 8 CSS or MTC-CSS (5) are composed of control channel elements from 0 to 15. The control channel elements constituting USS or MTC-USS (6) include a radio network temporary identifier (Radio （Network Temporary Identifier: RNTI) assigned by UE1 or MTCUE1 by a base station apparatus, an aggregation level, and a slot in a radio frame. It is determined based on the number of the. Here, at the time of initial access, the base station device transmits a temporary cell radio network temporary identifier (Temporary Cell-Radio Network Temporary Identifier: Temporary C-RNTI) to UE1 or MTCUE1 by including it in a random access response. Moreover, the base station apparatus may reset the cell radio network identifier (Cell-Radio Network Temporary Identifier: C-RNTI) of UE1 or MTCUE1 after the initial access.

(About SIB resource mapping)
FIG. 7 is a diagram illustrating an example of SIB resource mapping according to the first embodiment of the present invention. As shown in FIG. 7, the SIB corresponding to UE1 includes 13 system information blocks of SIB1 (7A to 7C) as system information block 1 (7) and SIB2 to 13 as system information blocks 2 to 13. include. The MTCUE1-compatible SIB includes 13 system information blocks SIB1 (7) and MTC-SIB2-13 (8A-8C) which are system information blocks 2-13 (8) compatible with MTCUE1. Yes. Here, SIB1 (7) is variable in the frequency resource and is transmitted in the PDSCH or MTC-PDSCH resource region within the MTCUE1-compatible downlink system bandwidth (for example, 5 MHz), fixed in the time resource, and transmitted in a period of 80 ms. Is done. Also, SIB1 (7) is retransmitted at 20 ms intervals. Also, SFN is transmitted to the fifth subframe region of a frame that is a multiple of 8.

Here, SIB2 to 13 are system information blocks corresponding to UE1, and both frequency resource and time resource are variably mapped (scheduled) to PDSCH. MTC-SIB2 to 13 (8) are system information blocks corresponding to MTCUE1, and both frequency resources and time resources are variably mapped (scheduled) to the resource area of MTC-PDSCH.

Furthermore, SIB1 (7) includes identification information such as an operator identifier, SIB2 to 13 and MTC-SIB2 to 13 (8) information of a period in which resources are repeatedly transmitted (System Information Window: SIW). Here, SIWs of SIB2 to 13 and MTC-SIB2 to 13 (8) may be used in common. The SIBs 2 to 13 include resource scheduling information, handover information, and the like. In particular, SIB2 includes PRACH resource scheduling information for UE1, and MTC-SIB2 includes common / shared channel information such as MTC-PRACH resource scheduling information for MTCUE1.

(Uplink radio frame configuration)
FIG. 8 is a diagram illustrating a configuration of an uplink radio frame according to the first embodiment of the present invention. As a time resource, a radio frame has a length of 10 ms and is composed of 10 subframes. The length of the subframe is 1 ms, and is composed of two slots. The slot length is 0.5 ms, and is composed of 7 SC-FDMA symbols. As a frequency resource, the uplink system bandwidth is composed of a plurality of SC-FDMA subcarriers. The frequency bandwidth of one subcarrier is 15 kHz, and the number of subcarriers depends on the downlink system bandwidth. A resource element, which is the minimum unit of radio resources, is composed of one subcarrier and one SC-FDMA symbol. A resource element is identified using a subcarrier number and an SC-FDMA symbol number.

One physical resource block is defined by 7 consecutive SC-FDMA symbols in the time domain and 12 consecutive subcarriers in the frequency domain. Therefore, one physical resource block is composed of (7 × 12) resource elements. One physical resource block corresponds to one slot in the time domain and corresponds to 180 kHz in the frequency domain. Physical resource blocks are numbered from 0 in the frequency domain.

(About physical uplink channel mapping)
FIG. 8 is a diagram illustrating an example of physical uplink channel mapping corresponding to UE1 according to the first embodiment of the present invention. As shown in FIG. 8, for example, the PUCCH is mapped with a plurality of physical resource blocks from both ends of the system frequency bandwidth. ULRS is mapped to the third SC-FDMA symbol. The PUSCH is mapped by avoiding the PUCCH and ULRS resource elements. The base station apparatus can frequency multiplex, time multiplex and / or spatially multiplex a plurality of PUSCHs.

FIG. 9 is a diagram illustrating an example of physical uplink channel mapping corresponding to MTCUE1 according to the first embodiment of the present invention. As illustrated in FIG. 9, for example, the resource element corresponding to MTCUE1 has an uplink system bandwidth (for example, 5 MHz) corresponding to MTCUE1 from one end (for example, a high frequency end) of the uplink system bandwidth (for example, 20 MHz) of the base station apparatus. ) Be placed within. Here, the uplink system bandwidth corresponding to MTCUE1 is narrower than the uplink system bandwidth (for example, 20 MHz) of the base station apparatus, and may have, for example, 1.4 MHz, 3 MHz, 5 MHz, 10 MHz, and 15 MHz.

As shown in FIG. 9, MTC-PUCCH (9) is mapped with a plurality of physical resource blocks from one end (eg, high frequency end) of the uplink band in the base station apparatus. That is, MTC-PUCCH (9) is arranged only at one end (for example, only at the high frequency end) of the uplink band in the base station apparatus. Here, how the MTC-PUCCH (9) is mapped to the uplink system bandwidth of the base station apparatus may be defined in advance by specifications or the like. Further, how the MTC-PUCCH (9) is mapped to the uplink system bandwidth of the base station apparatus may be set by the base station apparatus. MTCUE1 can transmit uplink control information using MTC-PUCCH (9). Here, for example, MTC-PUCCH (9) is multiplexed with PUCCH by code division. Further, for example, in the third SC-FDMA symbol, MTC-ULRS is mapped within the downlink system bandwidth (for example, 5 MHz) corresponding to MTCUE1. Also, MTC-PUSCH is mapped avoiding MTC-PUCCH (9) and MTC-ULRS resource elements. The base station apparatus can frequency-multiplex, time-multiplex and / or spatially multiplex a plurality of MTC-PUSCHs.

Here, since the resource region of MTC-PUSCH is the same as the resource region of PUSCH within the uplink system bandwidth corresponding to MTCUE1, MTC-PUSCH has the same meaning as PUSCH within the uplink system bandwidth compatible with MTCUE1. . In the base station apparatus, there is no collision between UE1 and MTCUE1 resource mapping in the two resource areas, and mapping (scheduling) can be performed appropriately.

(About PRACH resource mapping)
FIG. 10 is a diagram illustrating an example of mapping (scheduling) of PRACH resources according to the first embodiment of the present invention. Here, the PRACH resource is periodically scheduled in the PUSCH resource region by SIB2 transmitted by the base station apparatus. Also, for example, the PRACH resource is composed of six resource blocks and one subframe. Here, the purpose of using the PRACH is to synchronize the UE 1 and the base station apparatus in the uplink.

Here, the resources (10A to 10C) of MTC-PRACH (10), which are PRACH resources corresponding to MTCUE1, are periodically scheduled in the resource region of MTC-PUSCH by MTC-SIB2 transmitted by the base station apparatus. The Further, for example, the resource of MTC-PRACH (10) is composed of six resource blocks and one subframe. Here, the purpose of using MTC-PRACH (10) is to synchronize between MTCUE1 and the base station apparatus in the uplink.

As shown in FIG. 10, the base station apparatus schedules the PRACH resource in the PUSCH resource region and the MTC-PRACH (10) resources (10A to 10C) in the MTC-PUSCH resource region. That is, since the MTC-PUSCH resource area overlaps with a part of the PUSCH resource area, the base station apparatus does not overlap the PRACH resource area and the MTC-PRACH (10) resource area (10A to 10C). Can be scheduled. Also, as shown in FIG. 10, in consideration of the versatility of the base station apparatus, the base station apparatus can also be scheduled to overlap the PRACH resource area and the MTC-PRACH (10) resource area (10C). .

Here, the base station apparatus can store in advance the PRACH resource instructed to the mobile station apparatus and the position information of the resource area (10A to 10C) of the MTC-PRACH (10). In consideration of the versatility of the base station apparatus, the base station apparatus should not store in advance the PRACH resource and the location information of the resource area (10A to 10C) of the MTC-PRACH (10) instructed to the mobile station apparatus. You can also.

(About mobile station radio access procedures)
When the mobile station apparatus is connected to the base station apparatus by power-up or handover, the mobile station apparatus attach procedure (UE attach procedure), the mobile station apparatus startup procedure (UE startup procedure), the RRC connection establishment procedure (RRC connection establishment) ) Etc., connect with the base station device according to the connection procedure of the mobile station device, and after the connection procedure is completed, the mobile station device can make and receive calls, and can enter standby mode (RRC idle mode: RRC_IDLE) or wireless connection mode. It is possible to transition to (RRC connected mode: RRC_CONNECTED).

Here, the mobile station apparatus makes a cell search synchronized with the base station apparatus, acquires system information (for example, MIB and SIB) from the base station apparatus, and moves to the base station apparatus in order to transition to the standby mode or the wireless connection mode. Random access. Hereinafter, a system information acquisition procedure and a random access procedure in the mobile station apparatus will be described.

(How to get system information)
FIG. 11 is a diagram illustrating an example of a system information acquisition procedure of the mobile station apparatus according to the first embodiment of the present invention. Each procedure (steps S11 to S18) will be described below.

(Regarding step S11 in FIG. 11)
The mobile station apparatus performs cell search. The mobile station device performs a cell search for a cell to which a radio link is to be connected when the power is turned on, during a handover, or in a standby mode. The mobile station apparatus detects the maximum power SS, for example, the carrier frequency offset and OFDM symbol timing corresponding to the base station apparatus shown in FIG. The carrier frequency offset and the OFDM symbol timing correction are performed based on the detection result, and the PCI is identified. When the cell search is completed, the mobile station apparatus can demodulate the downlink OFDM signal of a specific base station apparatus, for example, the base station apparatus shown in FIG. As shown in FIG. 3, the downlink system bandwidth (for example, 20 MHz) that is the reception bandwidth of UE1, and the MTCUE1-compatible downlink system bandwidth (for example, 5 MHz) that is the reception bandwidth of MTCUE1 are the SS bandwidth. SS signal can be received.

(Regarding step S12 in FIG. 11)
The mobile station apparatus acquires MIB information. In the PBCH mapping configuration as shown in FIGS. 2, 3 and 6, the mobile station apparatus receives the PBCH from the base station apparatus, demodulates the MIB information, and determines the system bandwidth of the base station apparatus, SFN, SIB1 from the MIB information. Information such as the reception method of (7) is acquired. As shown in FIG. 3, the downlink system bandwidth (for example, 20 MHz) that is the reception bandwidth of UE1, and the MTCUE1-compatible downlink system bandwidth (for example, 5 MHz) that is the reception bandwidth of MTCUE1 are the bandwidths of the PBCH. PBCH signal can be received.

(Regarding step S13 in FIG. 11)
The mobile station apparatus acquires SIB1 (7) information. From the acquired MIB information, the mobile station apparatus uses the downlink system bandwidth (for example, 20 MHz) of the base station apparatus, the SIB1 (7) reception method, and the SFN information to indicate the downlink system band corresponding to MTCUE1 shown in FIG. The resource mapping position of SIB1 (7) within the width (for example, 5 MHz) is calculated, and SIB1 (7) information is acquired. As shown in FIG. 7, the base station apparatus that can support the mixture of UE1 and MTCUE1 is different from the conventional UE1 compatible base station apparatus, and the area of SIB1 (7) in advance is the downlink system bandwidth (compatible with MTCUE1) For example, scheduling is performed within 5 MHz. The downlink system bandwidth (for example, 20 MHz) that is the reception bandwidth of UE1, and the MTCUE1-compatible downlink system bandwidth (for example, 5 MHz) that is the reception bandwidth of MTCUE1 covers the bandwidth of SIB1 (7). Therefore, SIB1 (7) can be received.

(Regarding step S14 in FIG. 11)
The mobile station apparatus determines UE1 or MTCUE1. A mobile station apparatus judges UE1 or MTCUE1 from built-in mobile station apparatus capability information etc., and switches a processing procedure. That is, if it is MTCUE1, the process proceeds to step S17 (Yes), and if it is UE1, the process proceeds to step S15 (No). Here, if the mobile station apparatus has a single capability, this step is not necessary, and the corresponding step is passed and the process proceeds to each step of UE1 and MTCUE1.

(Regarding step S15 in FIG. 11)
UE1 receives CSS (decodes PDCCH in CSS). Here, in the case of UE1, UE1 receives the radio frame signal of the downlink system bandwidth (for example, 20 MHz) corresponding to UE1 transmitted from the base station apparatus, and after the cell search in step S11, 2 using the timing information such as subframe / slot / OFDM symbol, the system bandwidth of the base station apparatus obtained through the PBCH reception in step S12, and the SFN, etc., and the 0th OFDM symbol of the PDCCH shown in FIG. 1 can be demodulated, and the 1st and 2nd OFDM symbols of the subsequent PDCCH can be demodulated.

(Regarding step S16 in FIG. 11)
UE1 receives SIB2-13. That is, UE 1 calculates the CSS and USS resource mapping position corresponding to UE 1 shown in FIG. 5 by demodulating PDCCH information, and detects the DCI format of CSS. When the DCI format used for SIB scheduling is detected, UE1 acquires the scheduling information of SIB2-13 and receives the information of SIB2-13 shown in FIG.

(Regarding step S17 in FIG. 11)
MTCUE1 receives MTC-CSS (5) (decodes PDCCH in MTC-CSS (5)). That is, in the case of MTCUE1, MTCUE1 receives the radio frame signal of the downlink system bandwidth (for example, 5 MHz) corresponding to MTCUE1 transmitted from the base station apparatus, and the radio frame / subframe obtained through the cell search in step S11. Using the timing information such as frame / slot / OFDM symbol, the system bandwidth of the base station apparatus obtained through the PBCH reception in step S12, and the information such as SFN, 6 of MTC-PDCCH (4) shown in FIG. It is possible to demodulate the MTC-PCFICH and MTC-PHICH in the No. OFDM symbol and to demodulate the No. 5 and No. 4 OFDM symbols of the subsequent MTC-PDCCH (4). Alternatively, MTC-PCFICH and MTC-PHICH are demodulated from the first OFDM symbol in the second slot of MTC-PDCCH (11A to 11C) shown in FIG. 4a, and then MTC-PDCCH (11A to 11C) is demodulated. It can be demodulated.

(Regarding step S18 in FIG. 11)
MTCUE1 receives the necessary MTC-SIB among MTC-SIB2 to 13 (8). MTCUE1 calculates MTC-CSS (5) and MTC-USS (6) resource mapping positions corresponding to MTCUE1 shown in FIG. 5 by demodulating MTC-PDCCH (4) information, and the DCI format of MTC-CSS (5) Is detected. When the DCI format used for MTC-SIB scheduling is detected, MTCUE1 acquires scheduling information of MTC-SIB2 to 13 (8), and is necessary among MTC-SIB2 to 13 (8) shown in FIG. The information of the correct MTC-SIB is received.

(Random access procedure)
The random access procedure of the mobile station apparatus includes two access procedures of Contention based Random Access and Non-contention based Random Access. Here, Contention based Random Access is random access that may collide between mobile station apparatuses, and is normally performed random access. Non-contention based Random Access is a random access in which no collision occurs between mobile station devices, and in a special case such as a handover in order to quickly synchronize between the mobile station device and the base station device. This is performed in response to an instruction from the base station apparatus.

When the mobile station device performs random access, it transmits only the random preamble. The random access preamble is composed of a preamble part and a CP (Cyclic prefix) part. For the preamble portion, a RACH sequence, which is a signal pattern representing information, for example, CAZAC (Constant Amplitude Zero, Auto Auto Correlation Zone Code) sequence is used, and 64 types of sequences (sequence numbers 1 to 64) are represented by 6-bit information. Expressed.

FIG. 12a is a diagram showing an example of a RACH sequence group according to the first embodiment of the present invention. The 64 sequences are divided into three RACH sequence groups depending on the application. The sequences of group A and group B are selected when the mobile station apparatus itself selects the sequence and performs random access. The RACH sequence of group A is selected by the mobile station apparatus when the path loss between the mobile station apparatus and the base station apparatus is large (the radio channel quality is poor) or the transmission data capacity of message 3 is small . The RACH sequence of group B is selected by the mobile station apparatus when the path loss between the mobile station apparatus and the base station apparatus is small (the radio channel quality is good) and the transmission data capacity of message 3 is large. The RACH sequence of group C is notified from the base station apparatus to the mobile station apparatus when using the Non-contention based Random Access procedure. Note that the number of RACH sequences in each group is variable, and sequence information regarding the number of RACH sequences in each group is reported from the base station apparatus. The mobile station apparatus can perform Contention based Random Access using the RACH sequences of Groups A and B, and can perform Non-contention based Random Access using the RACH sequences of Group C.

When the mobile station apparatus performs Contention based Random Access, UE1 randomly selects a RACH sequence using sequence information related to PRACH, and MTCUE1 uses sequence information related to MTC-PRACH (10), and transmits a random access preamble. Hereinafter, sequence information related to PRACH is referred to as RACH sequence information, and sequence information related to MTC-RACH (10) is referred to as MTC-RACH (10) sequence information. Further, the RACH sequence information may be referred to as UE1-compatible random access preamble information, and the MTC-PRACH (10) sequence information may be referred to as MTCUE1-compatible random access preamble information.

Here, a new RACH sequence group D is added under the RACH sequence groups A, B, and C shown in FIG. 12b (the sequence number corresponding to each RACH sequence group is redefined), and the RACH sequence group D is added. A dedicated RACH sequence used only by MTCUE1 may be defined. That is, RACH sequence group D may include MTC-PRACH (10) sequence information.

FIG. 13 is an example of a random access (Contention based Random Access) procedure according to the first embodiment of the present invention. The mobile station apparatus can obtain SIB2 or MTC-SIB2 (8) information through the system information acquisition procedure (S11 to S18) shown in FIG. The SIB2 includes scheduling information of the PRACH resource region (PRACH resource region) corresponding to UE1 and RACH sequence information notified from the base station apparatus. MTC-SIB2 (8) includes scheduling information of MTC-PRACH resource region (MTC-PRACH resource region) (10A to 10C) and MTC-RACH (10) sequence information notified from the base station apparatus. It is included. Including the scheduling information of the MTC-PRACH resource region (10A to 10C) and the sequence information of the MTC-RACH (10), it is referred to as a resource related to the MTC-PRACH, and includes the scheduling information of the PRACH resource region and the sequence information of the RACH, This is referred to as a PRACH resource. Both the resource relating to PRACH and the resource relating to MTC-PRACH include resource region (frequency, time) and sequence information.

The base station apparatus notifies (assigns) the resource information about the PRACH to the mobile station apparatus using the SIB2 and the resource information about the MTC-PRACH using the MTC-SIB2 (8).

As shown in FIG. 10, the mapping (assignment) of the PRACH resource region and the MTC-PRACH resource region (10A to 10C) is performed without overlapping with the PRACH resource region like the MTC-PRACH resource region (10A, 10B). be able to. Alternatively, mapping can be performed by overlapping with the PRACH resource region as in the MTC-PRACH resource region (10C).

The base station apparatus can store in advance the PRACH resource area and MTC-PRACH (10) resource area (10A to 10C) location information (frequency, time) notified to the mobile station apparatus. Also, considering the versatility of the base station apparatus, the base station apparatus should not store in advance the location information of the PRACH resource area and the MTC-PRACH (10) resource area (10A to 10C) instructed to the mobile station apparatus. You can also.

(Regarding step S21 in FIG. 13)
The mobile station apparatus transmits a random access preamble as a message 1 to the base station apparatus. In the case of UE1, UE1 receives PRACH resource information from SIB2, and in the PRACH resource area notified from the base station apparatus as shown in FIG. 10, the RACH sequence randomly selected by the RACH sequence information. The PRACH random access preamble is transmitted to the base station apparatus. In the case of MTCUE1, MTCUE1 receives information on resources related to MTC-PRACH from MTC-SIB2 (8), and as shown in FIG. 10, the MTC-PRACH resource region (10A˜10) corresponding to MTCUE1 notified from the base station apparatus. 10C), the random access preamble of MTC-PRACH (10) is transmitted to the base station apparatus using the RACH sequence randomly selected by the sequence information of MTC-RACH (10). That is, UE1 can transmit a random access preamble to a base station apparatus using the resource area | region of PRACH notified by the base station apparatus, and the selected RACH sequence. Further, MTCUE1 can transmit a random access preamble to the base station apparatus using the MTC-PRACH resource region (10A to 10C) notified by the base station apparatus and the selected RACH sequence.

Specifically, in the case of UE1, UE1 receives PRACH resource information notified from the base station apparatus, and uses the RACH sequence information included in the PRACH resource information to transmit a downlink path loss or message 3 ( The sequence group A or B shown in FIG. 12a is selected based on the data size described later. One CAZAC sequence is randomly selected from the selected sequence group, a random access preamble is generated based on the selected CAZAC sequence, and the PRACH resource region information included in the PRACH resource information is used to generate a random access preamble. A random access preamble (message 1) is transmitted on the access channel RACH.

Also, in the case of MTCUE1, MTCUE1 receives information on resources related to MTC-PRACH notified from the base station apparatus, and uses the MTC-RACH sequence information included in the information on resources related to MTC-PRACH, and uses the MTC-RACH sequence information. And sequence group A or B is selected based on the data size of message 3. One CAZAC sequence is randomly selected from the selected sequence group, a random access preamble is generated based on the selected CAZAC sequence, and MTC-PRACH resource region information included in the resource information about the MTC-PRACH is obtained. The random access preamble (message 1) is transmitted using the random access channel RACH.

Alternatively, in the case of MTCUE1, MTCUE1 receives information on resources related to MTC-PRACH notified from the base station apparatus, and uses the MTC-RACH sequence information included in the information on resources related to MTC-PRACH, as shown in FIG. One CAZAC sequence is randomly selected from the selected sequence group D, a random access preamble is generated based on the selected CAZAC sequence, and MTC-PRACH resource region information included in the resource information related to MTC-PRACH is obtained. The random access preamble (message 1) is transmitted using the random access channel RACH.

(Regarding step S22 in FIG. 13)
When the base station apparatus receives a random access preamble, that is, message 1, in order to transmit a random access response as a message 2 to the mobile station apparatus as a response to message 1, is the received message 1 a transmission from UE1? Judge whether or not.

For example, the base station apparatus determines whether or not it is the message 1 from the UE 1 by identifying whether or not the resource area of the random access preamble from the mobile station apparatus is a PRACH resource area. Specifically, when a random access preamble is detected in the PRACH resource area as shown in FIG. 10, the base station apparatus notifies the mobile station apparatus and stores the location of the PRACH resource area stored in advance. Since it is the same resource area as compared with the information, it is determined as random access from UE1, and the process proceeds to step S24 (Yes). On the other hand, when the base station apparatus notifies the mobile station apparatus and no random access preamble is detected in the resource area of the PRACH stored in advance, the base station apparatus proceeds to step S23 (No).

(Regarding step S23 in FIG. 13)
When the base station apparatus receives a random access preamble, that is, message 1, in order to transmit a random access response as a message 2 to the mobile station apparatus as a response to message 1, is the received message 1 a transmission from MTCUE1? Judge whether or not.

For example, the base station apparatus determines whether or not it is the message 1 from the MTCUE1 by identifying whether or not the resource area of the random access preamble from the mobile station apparatus is the MTC-PRACH resource area (10A to 10C). . Specifically, when a random access preamble is detected in the resource region (10A) of the MTC-PRACH as shown in FIG. 10, the base station device notifies the mobile station device and stores the MTC stored in advance. -Compared with the location information of the PRACH resource region (10A), since it is the same resource region, it is determined as random access from MTCUE1, moves to step S25 (Yes), and notifies the mobile station apparatus. If the resource related to RACH and the resource related to MTC-RACH are the same and it cannot be determined whether the received message 1 is message 1 from UE1 or message 1 from MTCUE1, the process proceeds to step S26 (No).

(Regarding step S24 in FIG. 13)
When the base station apparatus detects the random access preamble transmitted by the UE1, the base station apparatus calculates a transmission timing shift amount between the UE1 and the base station apparatus from the random access preamble, and outputs the L2 / L3 message in the PUSCH, that is, the message 3 Resource scheduling for transmission, for example, uplink radio resource location, transmission format (message size), etc. are specified, Temporary C-RNTI (Cell-Radio Network Temporary Identity) is assigned, and PRACH is assigned to CSS RA-RNTI (Random Access Network Temporary Identity) indicating a response (random access response) addressed to UE1 that has transmitted the random access preamble of Transmission timing gap information to the CH, scheduling information, to place the random access response message including the Temporary C-RNTI and the received preamble preamble number (sequence number), and transmits the message 2 of the UE1. For example, the DCI format 1A is used as the DCI format used for scheduling the random access response.

(Regarding step S25 in FIG. 13)
When the base station apparatus detects a random access preamble transmitted by MTCUE1, the base station apparatus calculates a transmission timing deviation amount between MTCUE1 and the base station apparatus from the random access preamble, and an L2 / L3 message in MTC-PUSCH, that is, a message 3, resource scheduling for transmitting 3, for example, uplink radio resource position, transmission format (message size) and so on, Temporary C-RNTI is assigned, MTC-CSS (5) MTC-RACH random access preamble An RA-RNTI indicating a response (random access response) addressed to MTCUE1 that has been transmitted is arranged, transmission timing deviation information, scheduling information, and Temporary C in the MTC-PDSCH. Including RNTI and the received preamble preamble number (sequence number) Place the random access response message, it sends a message 2 of MTCUE1. That is, for example, in the MTC-CSS (5), the base station apparatus arranges the MTC-PDCCH (4) with the CRC scrambled with the RA-RNTI. That is, for example, in the MTC-CSS (5), the base station apparatus transmits downlink control information with a CRC in which the RA-RNTI is scrambled using the MTC-PDCCH (4).

(Regarding step S26 in FIG. 13)
When the base station apparatus cannot determine the random access preamble from UE1 or the random access preamble from MTCUE1, the base station apparatus calculates the transmission timing shift amount between the mobile station apparatus and the base station apparatus from the random access preamble, and PUSCH Resource scheduling for transmitting L2 / L3 message, that is, message 3 in both MTC and MTC-PUSCH, eg, uplink radio resource position, transmission format (message size), etc. are specified, and Temporary C-RNTI (Cell-RadioNetwork Temporary RA: R-NTT indicating a response (random access response) addressed to the mobile station device which has assigned a random access preamble to both CSS and MTC-CSS (5). I is arranged, a random access response message including transmission timing deviation information, scheduling information, Temporary C-RNTI, and preamble number (sequence number) of the received preamble is arranged on the PDSCH and MTC-PDSCH, and the mobile station apparatus message 2 Send.

Note that the radio resources scheduled in the mobile station apparatus by the random access responses in steps 24, 25, and 26 are only one resource block (one subframe).

(Regarding step S27 in FIG. 13)
The mobile station apparatus determines whether the own station is UE1 or MTCUE1. A mobile station apparatus judges whether it is UE1 or MTCUE1 from built-in mobile station apparatus capability information etc., and switches a processing procedure. If it is MTCUE1, the process proceeds to step S28 (Yes), and if it is UE1, the process proceeds to step S29 (No). However, if the mobile station apparatus has a single capability, this step is unnecessary, and the corresponding step is passed and the process proceeds to each step of UE1 and MTCUE1.

(Regarding step S28 in FIG. 13)
UE1 receives message 2 of UE1. When UE1 detects the presence of RA-RNTI in CSS, it confirms the content of the random access response message arranged in PDSCH, and if the preamble number corresponding to the transmitted random access preamble is included, message 2 of UE1 Extract information.

(Regarding step S29 in FIG. 13)
MTCUE1 receives MTCUE1 message 2. When MTCUE1 detects the presence of RA-RNTI in MTC-CSS (5), MTCUE1 confirms the content of the random access response message arranged in MTC-PDSCH and includes the preamble number corresponding to the transmitted random access preamble. If so, the information of message 2 of MTCUE1 is extracted. That is, for example, MTCUE1 monitors MTC-PDCCH (4) with CRC in which RA-RNTI is scrambled in MTC-CSS (5). That is, for example, MTCUE1 monitors the downlink control information accompanied by CRC in which RA-RNTI is scrambled in MTC-CSS (5).

(Regarding step S30 in FIG. 13)
The mobile station apparatus corrects the transmission timing shift using the extracted message 2 information, and uses the scheduled C-RNTI (or C-RNTI) and IMSI (International Mobile Subscriber Identity) in the scheduled radio resource and transmission format. The L2 / L3 message including information for identifying the mobile station device such as the message 3 is transmitted.

The mobile station device continues to wait for a certain period of time for the random access response message from the base station device, and if it does not receive the random access response message including the preamble number of the transmitted random access preamble, it again transmits the random access preamble. To do.

(Regarding step S31 in FIG. 13)
When the base station apparatus receives the L2 / L3 message, that is, the message 3, in order to transmit a collision confirmation (contention resolution) message to the mobile station apparatus as a response to the message 3, It is determined whether it is message 3 from MTCUE1. As an example of the determination, a determination is made based on the PUSCH radio resource assigned to which mobile station apparatus the L2 / L3 message transmitted from the mobile station apparatus.

(Regarding step S32 in FIG. 13)
If the message 3 transmitted from the mobile station device is a radio resource of PUSCH assigned to UE1, the base station device arranges Temporary C-RNTI (or C-RNTI) included in the L2 / L3 message in CSS. Then, the collision confirmation message including the identification information of the mobile station apparatus included in the message 3 is arranged in the PDSCH, and the message 4 of the UE 1 is transmitted.

(Regarding step S33 in FIG. 13)
If the message 3 transmitted from the mobile station device is a radio resource of the MTC-PUSCH allocated to MTCUE1, the base station device uses the Temporary C-RNTI (included in the L2 / L3 message in MTC-CSS (5)). Or C-RNTI), a collision confirmation message including the identification information of the mobile station apparatus included in message 3 is arranged in MTC-PDSCH, and message 4 of MTCUE1 is transmitted.

(About Step S34 in FIG. 13)
The mobile station apparatus determines UE1 or MTCUE1. A mobile station apparatus judges UE1 or MTCUE1 from built-in mobile station apparatus capability information etc., and switches a processing procedure. If it is MTCUE1, the process proceeds to step S36 (Yes), and if it is UE1, the process proceeds to step S35 (No). However, if the mobile station apparatus has a single capability, this step is unnecessary, and the corresponding step is passed and the process proceeds to each step of UE1 and MTCUE1.

(Regarding step S35 in FIG. 13)
UE1 receives the message 4 of UE1. When the UE 1 detects that the CSS has Temporary C-RNTI, the UE 1 confirms the content of the collision confirmation message arranged in the PDSCH, and if the identification information of the own mobile station device is included, the random access procedure is terminated.

(Regarding step S36 in FIG. 13)
MTCUE1 receives message 4 of MTCUE1. When MTCUE1 detects the presence of Temporary C-RNTI in MTC-CSS (5), it confirms the content of the collision confirmation message arranged in MTC-PDSCH, and if the identification information of its own mobile station device is included, End the random access procedure. For example, MTCUE1 monitors MTC-PDCCH (4) with CRC in which Temporary C-RNTI is scrambled in MTC-CSS (5).

The mobile station apparatus does not detect a random access response message including a preamble number corresponding to the random access preamble transmitted within a certain period, fails to transmit message 3, or collides within a certain period. If the identification information of the mobile station apparatus is not detected in the confirmation message, the process starts again from transmission of the random access preamble (message 1). After the random access procedure is completed, control data for connection is further exchanged between the base station apparatus and the mobile station apparatus.

After the random access is completed, the RRC connection establishment procedure (RRC Connection Establishment Procedure) defined in the LTE specifications is performed between the mobile station device and the base station device, and the standby mode is changed to the wireless connection mode.

The mobile station apparatus transmits a mobile station apparatus capability message during the RRC connection establishment procedure or after the RRC connection establishment procedure. The mobile station apparatus transmits a mobile station apparatus capability signal indicating UE1 or MTCUE1 using a mobile station apparatus capability transmission procedure (UE Capability Transfer) defined in the LTE specification. The mobile station apparatus sends a UE1 or MTCUE1 message to a mobile station apparatus capability (UE Capability Information, or UE EUTRA Capability Information) message, which is one of the RRC messages defined in the LTE specification, as the format of the mobile station apparatus capability signal. Use the information added.

Here, in the mobile station apparatus capability message (UE Capability Information, or UE EUTRA Capability Information), for example, 1 bit (or a plurality of encoded bits) indicating UE1 or MTCUE1, or a plurality of bits related to UE1 or MTCUE1 Information bits.

For example,
-ASN1START
UE-EUTRA-Capability :: = SEQUENCE {
・ ・ ・ ・ ・ ・
MTC-Capability ENUMERATED {supported},-“1” = MTCUE1; “0” = UE1
}
-ASN1STOP
As shown in the above, a mobile station apparatus capability signal indicating UE 1 or MTCUE 1 described in the abstract syntax notation ASN (Abstract Syntax Notation) is added, for example, an MTC-Capability message. .

The mobile station apparatus capability message to which the mobile station apparatus capability signal is added is converted into an information bit string by the ASN encoder process according to the configuration of the mobile station apparatus to be described later, and the mobile station apparatus capability transmission procedure (UE Capability Transfer) to the base station device.

The base station apparatus extracts an information bit string by an ASN decoder process according to the configuration of the mobile station apparatus to be described later, and information on the mobile station apparatus capability message, for example, MTC-Capability information, that is, mobile station apparatus capability indicating UE1 or MTCUE1 The signal is decoded and stored as a mobile station apparatus capability in a base station apparatus and / or a core network (not shown) connected to the base station apparatus.

Further, as illustrated in FIG. 13, the uplink bandwidth of MTCUE1 is narrower than the uplink system bandwidth (for example, 20 MHz) of the base station device, and the uplink system bandwidth (for example, 20 MHz) of the base station device. Although mapped to the high frequency end, it is the same as the uplink system bandwidth (for example, 20 MHz) of the base station apparatus or narrower than the uplink system bandwidth (for example, 20 MHz) of the base station apparatus, and the uplink of the base station apparatus Mapping to the lower frequency end of the system bandwidth (for example, 20 MHz) or narrower than the uplink system bandwidth (for example, 20 MHz) of the base station apparatus and the center frequency f2 of the uplink system bandwidth (for example, 20 MHz) of the base station apparatus Can also be done.

Note that the uplink information of MTCUE1, such as the uplink bandwidth, frequency position of MTCUE1, and the resource region (10A to 10B) of MTC-PRACH (10), is notified by MTC-SIB2 (8).

(About paging transmission procedure of base station equipment)
The base station apparatus can identify whether the mobile station apparatus is UE1 or MTCUE1 by the random access procedure shown in FIG. Further, the base station apparatus can identify whether the mobile station apparatus is UE1 or MTCUE1 based on the mobile station apparatus capability notified from the mobile station apparatus. FIG. 14 is a diagram illustrating an example of a paging transmission procedure of the base station apparatus.

(Regarding step S101 in FIG. 14)
The base station apparatus detects whether a paging message needs to be transmitted to UE1 or MTCUE1. The base station device detects that the paging message needs to be transmitted, for example, when the base station device is requested by the host control device for a call notification of the mobile station device, the cell managed by the base station device This is when it is necessary to update the system information, and when a notification from the host controller is received that an earthquake and tsunami warning (ETWS) notification is necessary.

(Regarding step S102 in FIG. 14)
The base station apparatus that has detected that transmission of a paging message is necessary identifies whether the mobile station apparatus that is the transmission target of paging is UE1 or MTCUE1 by the procedure of FIG. The base station apparatus determines UE1 or MTCUE1, and switches the paging transmission procedure. That is, if it is MTCUE1, the process proceeds to step S104 (Yes), and if it is UE1, the process proceeds to step S103 (No). However, when it is necessary to transmit a paging message for all mobile station devices, for example, notification of an earthquake tsunami warning (ETWS), the base station device does not perform the determination of step S102, but performs step S103 and step S103. You may perform both transmission procedures of S104.

(Regarding step S103 in FIG. 14)
The base station apparatus that has been requested to notify the call to UE1 transmits a PDCCH with a CRC scrambled with RNTI (P-RNTI) for UE1 in the CSS of the downlink system bandwidth (for example, 20 MHz) corresponding to UE1. Send. At this time, the base station apparatus arranges the identifier of the UE 1 to be paged (temporary service subscriber identifier: S-TMSI, international subscriber identifier: IMSI) in the paging message. And a base station apparatus transmits the paging message by which the identifier of UE1 is arrange | positioned by PDSCH.

The base station apparatus that has detected that the system information for UE1 needs to be updated, transmits a PDCCH with a CRC scrambled for RNTI (P-RNTI) for UE1 to the downlink system bandwidth corresponding to UE1 ( For example, transmission is performed using CSS of 20 MHz. At this time, the base station apparatus arranges information indicating update of the system information in the paging message transmitted by the PDSCH. And a base station apparatus transmits the paging message by which the information which shows the update of the system information with respect to UE1 is arrange | positioned by PDSCH. Also, the base station apparatus updates the system information that needs to be updated at a timing that becomes the update period (modification period) of the system information, and transmits the information using the PDSCH.

The base station apparatus that has detected that the notification of the earthquake tsunami warning (ETWS) to UE1 is necessary, transmits the PDCCH with the CRC scrambled with the RNTI for paging (P-RNTI) to UE1. It transmits with CSS of system bandwidth (for example, 20 MHz). At this time, the base station apparatus arranges information indicating a notification of an earthquake tsunami warning (ETWS) in a paging message transmitted by PDSCH. And a base station apparatus transmits the paging message by which the information which shows the notification of the earthquake tsunami warning (ETWS) with respect to UE1 is arrange | positioned by PDSCH. In addition, the base station apparatus transmits system information related to information on the earthquake tsunami warning (ETWS) using MTC-PDSCH.

(Regarding step S104 in FIG. 14)
The base station apparatus that has been requested to make a call notification to MTCUE1 uses MTC-PDCCH (4) with a CRC scrambled for RNTI (P-RNTI) for MTCUE1 as a downlink system bandwidth corresponding to MTCUE1 (for example, (5 MHz) MTC-CSS (5). At this time, the base station apparatus arranges the identifier of MTCUE1 that is the target of paging in the paging message. Then, the base station apparatus transmits a paging message in which the identifier of MTCUE1 is arranged using MTC-PDSCH.

The base station apparatus that has detected that the system information for MTCUE1 needs to be updated, downloads MTC-PDCCH (4) with a CRC in which RNTI (P-RNTI) for paging is scrambled with respect to MTCUE1. Transmission is performed by MTC-CSS (5) having a link system bandwidth (for example, 5 MHz). At this time, the base station apparatus arranges information indicating the update of the system information in the paging message transmitted by the MTC-PDSCH. Then, the base station apparatus transmits a paging message in which information indicating update of system information for MTCUE1 is arranged using MTC-PDSCH. In addition, the base station apparatus updates the system information that needs to be updated at a timing that is a system information update period (modification period), and transmits the system information using MTC-PDSCH.

The base station apparatus that has detected that the notification of the earthquake and tsunami warning (ETWS) to MTCUE1 is necessary requires MTC-PDCCH (4) with CRC in which RNTI (P-RNTI) for paging is scrambled for MTCUE1. Transmission is performed using MTC-CSS (5) having a downlink system bandwidth (for example, 5 MHz) corresponding to MTCUE1. At this time, the base station apparatus arranges information indicating a notification of an earthquake tsunami warning (ETWS) in a paging message transmitted by MTC-PDSCH. Then, the base station apparatus transmits a paging message in which information indicating a notification of an earthquake tsunami warning (ETWS) to MTCUE1 is arranged using MTC-PDSCH. In addition, the base station apparatus transmits the system information MTC-PDSCH related to the information on the earthquake tsunami warning (ETWS).

That is, the base station apparatus can use different paging transmission procedures by identifying whether the mobile station apparatus is UE1 or MTCUE1. For example, the base station apparatus notifies the UE 1 of paging by transmitting the PDCCH in which the P-RNTI is arranged by using CSS, and the MTC-PDCCH (4) in which the P-RNTI is arranged as the MTC-CSS. Notification is made by transmitting in (5).

(About the paging reception procedure of the mobile station device)
The MTCUE1 in the standby mode periodically monitors the MTC-PDCCH (4) in the MTC-CSS (5) and detects the transmission of the paging message. A paging message for MTCUE1 is transmitted by placing an RNTI for paging (P-RNTI) in MTC-PDCCH (4). When MTCUE1 detects the presence of P-RNTI in MTC-CSS (5), MTCUE1 receives the paging message arranged in MTC-PDSCH, and identifies its own station (temporary service subscriber identifier: S-) in the paging message. It is confirmed whether TMSI and international subscriber identifier (IMSI) are allocated. If the local station identifier (S-TMSI and IMSI) is allocated, the RRC connection establishment procedure is started.

The MTCUE1 in the standby mode or the wireless connection mode monitors the MTC-PDCCH (4) in the MTC-CSS (5) and detects whether the system information update or the earthquake tsunami warning (ETWS) is included in the paging message. To do. When MTCUE1 detects the presence of P-RNTI in MTC-CSS (5), it receives the paging message placed on MTC-PDSCH and checks whether system information update or earthquake tsunami warning (ETWS) is included To do.

By adopting the configuration as described above, a mobile station apparatus compatible with machine type communication can efficiently communicate. For example, a mobile station apparatus that supports machine type communication can efficiently communicate with a base station apparatus while having backward compatibility with a conventional system. Also, a low-cost MTC device or MTC terminal is provided by narrowing the downlink frequency bandwidth (reception bandwidth) and / or the uplink frequency bandwidth (transmission bandwidth) of the mobile station apparatus that supports machine type communication. can do.

(About the configuration of the base station device)
FIG. 15 is a diagram illustrating a configuration of the base station apparatus according to the first embodiment of the present invention. The base station apparatus includes an interface unit, an upper layer processing unit (3), a physical channel generation unit (3), a multiplexing unit (3), a transmission unit (3), a transmission antenna unit (3), a reception antenna unit (3), A receiving unit (3), a demultiplexing unit (3), a physical channel demodulating unit (3), and a control unit (3) are provided. The physical channel generation unit (3) includes a common channel generation unit (3), a UE1-compatible channel generation unit (3), and an MTCUE1-compatible channel generation unit (3). The physical channel demodulation unit (3) includes a UE1-compatible channel demodulation unit (3) and an MTCUE1-compatible channel demodulation unit (3).

The common channel generation unit (3) generates DLRS, SS, and PBCH signals of common channels that are commonly received by the UE1 and the MTCUE1 illustrated in FIG. As shown in FIG. 1, the UE1-compatible channel generation unit (3) generates PDCCH, PCFICH, PHICH, and PDSCH signals of channels received by the UE1. As shown in FIG. 1, the MTCUE1-compatible channel generation unit (3) generates MTC-PDCCH (4), MTC-PCFICH, MTC-PHICH, and MTC-PDSCH signals of channels received by MTCUE1.

In the case of UE1, the multiplexing unit (3) is DLRS, SS, PBCH, PDCCH, PCFICH, PHICH generated by the common channel generation unit (3) and the UE1-compatible channel generation unit (3), as shown in FIG. The PDSCH signal is mapped to a downlink radio frame, a downlink radio frame baseband signal is generated, and sent to the transmission unit (3). Further, as shown in FIG. 3 or 4a, the multiplexing unit (3) generates a common channel generation unit (3), a UE1-compatible channel generation unit (3), and an MTCUE1-compatible channel generation when UE1 and MTCUE1 coexist. DLRS, SS, PBCH, PDCCH, PCFICH, PHICH, PDSCH, MTC-PDCCH (4), MTC-PCFICH, MTC-PHICH, MTC-PDSCH signals generated by the unit (3) are mapped to downlink radio frames, Further, a fast inverse Fourier transform IFFT (Inverse Fourier Transform) and a guard interval GI (Guard Interval) are inserted to generate a baseband signal of a downlink radio frame and send it to the transmitter (3).

The transmission unit (3) performs digital / analog conversion on the downlink radio frame baseband signal output from the multiplexing unit (3), performs filter processing such as bandwidth limitation, and orthogonal modulation processing to generate a predetermined RF signal. Further, the RF signal is amplified to a predetermined output power and output to the transmission antenna unit (3). FIG. 13 shows one transmission antenna unit (3) and one transmission unit (3). However, according to the layer mapping process of each downlink physical channel, a plurality of transmission antenna units (3) and It is good also as providing a some transmission part (3).

The receiving unit (3) receives an RF signal of a predetermined uplink physical channel from the receiving antenna unit (3), performs amplification, frequency conversion, filter processing, quadrature demodulation processing, analog / digital conversion, etc., and obtains the result. The uplink physical channel signal is output to the demultiplexing unit (3). FIG. 15 shows one receiving antenna unit (3) and one receiving unit (3). However, according to the layer mapping process of each uplink physical channel, a plurality of receiving antenna units (3) and It is good also as providing a some receiving part (3). FIG. 15 shows the transmitting antenna unit (3) and the receiving antenna unit (3) separately. However, in the FDD mode base station apparatus, the antenna duplexer DUP (Duplexer) is connected to the TDD mode base station apparatus. Then, by using the antenna switching unit SW (Switch), it is possible to use one common antenna.

The demultiplexing unit (3) performs OFDM symbol timing detection, guard interval GI removal, and fast Fourier transform FFT (Fast Fourier Transform) on the uplink physical channel signal received from the mobile station apparatus. 8, when the baseband signal of the uplink radio frame shown in FIG. 8 is generated and UE1 and MTCUE1 are mixed, the baseband signal of the radio frame of the uplink system bandwidth (for example, 20 MHz) shown in FIG. Then, each physical channel is extracted and output to the physical channel demodulator (3).

The UE1-compatible channel demodulation unit (3) demodulates ULRS, PUCCH, PUSCH, and PRACH signals transmitted from the UE1 shown in FIG. The MTCUE1-compatible channel demodulation unit (3) demodulates the MTC-ULRS, MTC-PUCCH (9), MTC-PUSCH, and MTC-PRACH (10) signals transmitted from the MTCUE1 shown in FIG.

Control unit (3) controls each block. For example, the control unit (3) performs timing control, on / off control of each block, measurement of uplink radio channel conditions, uplink and downlink radio resource scheduling, processing of predetermined communication protocols and procedures, and the like. The interface unit is connected to a core network (not shown), and transmits and receives user data and control data.

The upper layer processing unit (3) is connected to the core network through the interface unit, and performs generation processing and extraction processing of upper layer user data and control data. The upper layer processing unit (3) performs various communication protocols and procedure processes. The upper layer processing unit (3) includes a data control unit (3).

Through the control unit (3), the data control unit (3) generates SIB1 (7) related data in the PBCH, as shown in FIG. 3, MTC-PDCCH (4), MTC-PCFICH, MTC-PHICH, and Generation of MTC-PCSCH related data, generation of downlink radio frame control data, and transmission to the mobile station apparatus are controlled. Further, as shown in FIG. 7, the data control unit (3) moves the MTC-SIB2 into the resource area (7A to 7C) of the SIB1 (7) within the downlink system bandwidth (for example, 5 MHz) corresponding to the MTCUE1. Control is performed so that resource mapping is performed in the resource areas (8A to 8C) of ˜13 (8). The system information acquisition procedure of the mobile station apparatus shown in FIG. 11 can be operated by the control of the data control unit (3).

Further, as shown in FIG. 7, the data control unit (3) performs resource mapping to the resource region (10A to 10C) of the SIB2 (10) within the uplink system bandwidth (for example, 5 MHz) corresponding to MTCUE1. To control. When a random access preamble of PRACH or MTC-PRACH (10) transmitted from the mobile station apparatus is received by the physical channel demodulator (3), CSS, MTC-CSS (5), or CSS and MTC-CSS ( 5) Control to send a random access response (message 2) to both parties. The random access procedure shown in FIG. 13 can operate under the control of the data control unit (3).

Further, the data control unit (3) controls reception of the mobile station apparatus capability message to which the mobile station apparatus capability signal is added through the mobile station apparatus capability transmission procedure (UE Capability Transfer). The upper layer processing unit (3) includes an ASN decoder, an information bit string is extracted by the ASN decoder process, and information on the mobile station apparatus capability message, for example, information on MTC-Capability, that is, UE1 or MTCUE1. The mobile station apparatus capability signal shown is decoded and stored in the base station apparatus as the mobile station apparatus capability.

Further, the data control unit (3) transmits a UE1-compatible paging message to the UE1-compatible channel generation unit (3) and an MTCUE1-compatible channel generation unit (3) through the paging transmission procedure of the base station apparatus. Corresponding paging messages can be inserted.

Here, the case where the base station apparatus transmits / receives an OFDM signal has been described. However, the present invention is not limited to this, and the base station apparatus can perform SC-FDMA scheme by the mobile station apparatus by changing the function of the circuit block. The uplink signal transmitted in step 1 may be received. Alternatively, an uplink signal transmitted by SC-FDMA (Clustered DFT-S-OFDM or CL-DFT-S-OFDM (Clustered Discrete Fourier Transform Spread OFDM)) method in which uplink frequency bands are not continuous may be received. Further, the configuration of the base station apparatus shown in FIG. 15 may correspond to any of the FDD mode, the TDD mode, or the dual mode of FDD / TDD.

(About configuration of mobile station equipment)
FIG. 16 is a diagram illustrating the configuration of the MTCUE 1 according to the first embodiment of the present invention. The MTCUE 1 includes a transmission / reception antenna unit 1, an antenna duplexer 1, a reception unit 1, a demultiplexing unit 1, a physical channel demodulation unit 1, a physical channel generation unit 1, a physical channel generation unit 1, a multiplexing unit 1, a transmission unit 1, and a control. Unit 1 and higher layer processing unit 1. The transmission / reception antenna unit 1 receives a signal from the base station apparatus shown in FIG. A reception signal from the transmission / reception antenna unit 1 is input to the antenna duplexer 1, while a transmission signal from the transmission unit 1 is transmitted by the transmission / reception antenna unit 1.

The receiving unit 1 performs amplification, frequency conversion, quadrature demodulation, filtering, analog / digital conversion processing, etc., on the received signal from the antenna duplexer 1. Since the frequency band of the receiving unit 1 is limited to the MTCUE1-compatible downlink frequency bandwidth (for example, 5 MHz), the baseband signal of the radio frame configuration of the MTCUE1-compatible downlink frequency bandwidth (for example, 5 MHz) illustrated in FIG. Is output to the demultiplexing unit 1.

The demultiplexing unit (1) performs OFDM symbol timing detection, guard interval GI removal, and fast Fourier transform FFT (Fast Fourier Transform) on the downlink physical channel signal received from the base station apparatus, as shown in FIG. Each physical channel signal is extracted from the baseband signal of the radio frame having the MTCUE1-compatible downlink system bandwidth (for example, 5 MHz) and output to the physical channel demodulator (1). The physical channel demodulation unit (1) includes a common channel unit (1) and an MTCUE1-compatible channel demodulation unit (1).

The common channel section (1) demodulates the DLRS, SS, and PBCH signals of the common channels that the UE1 and MTCUE1 shown in FIG. 1 receive in common. As shown in FIG. 1, the MTCUE1-compatible channel demodulation unit (1) demodulates the MTC-PDCCH (4), MTC-PCFICH, MTC-PHICH, and MTC-PDSCH signals of channels received by the MTCUE1.

The physical channel generation unit (1) includes an MTCUE1-compatible channel generation unit (1). As shown in FIG. 1, the MTCUE1-compatible channel generation unit (1) receives MTC-ULRS, MTC-PUCCH (9), MTC-PUSCH, and MTC-PRACH (10) signals of channels received by the base station apparatus. Generate. The UE1-compatible channel demodulator (1) demodulates ULRS, PUCCH, PUSCH, and PRACH signals transmitted from the UE1 shown in FIG. The MTCUE1-compatible channel demodulation unit (1) demodulates the MTC-ULRS, MTC-PUCCH (9), MTC-PUSCH, and MTC-PRACH (10) signals transmitted from the MTCUE1 shown in FIG.

Control unit (1) controls each block. For example, the control unit (1) performs timing control of each block, on / off control, measurement of uplink radio channel conditions, uplink and downlink radio resource scheduling, control by a predetermined communication protocol and procedure, and the like. In addition, as shown in FIG. 9, the multiplexing unit (1) includes the MTC-ULRS, MTC-PUCCH (9), MTC-PUSCH, and MTC-PRACH (10) generated by the MTCUE1-compatible channel generation unit (1). The signal is mapped to an uplink radio frame, and further, a fast inverse Fourier transform IFFT (Inverse Fourier Transform) and a guard interval GI (Guard Interval) are inserted, and the downlink frequency bandwidth corresponding to MTCUE1 shown in FIG. 3 or 4a A baseband signal of a radio frame (for example, 5 MHz) is generated and sent to the transmission unit (1).

The transmission unit (1) performs digital / analog conversion on the uplink radio frame baseband signal output from the multiplexing unit (1), performs filter processing such as bandwidth limitation, and orthogonal modulation processing to generate a predetermined RF signal. Then, the RF signal is amplified to a predetermined output power and output to the transmission / reception antenna unit (1) through the antenna duplexer (1).

The upper layer processing unit (1) performs generation processing and extraction processing of upper layer user data and control data, and also performs various communication protocols and procedure processing. The upper layer processing unit (1) includes a data control unit (1). Through the control unit (1), the data control unit (1) generates related data of MTC-ULRS, MTC-PUCCH (9), MTC-PUSCH, and MTC-PRACH (10) as shown in FIG. Controls generation of downlink radio frames and transmission to mobile station apparatuses.

Further, as shown in FIG. 9, the data control unit (1) performs resource mapping to MTC-ULRS, MTC-PUCCH, and MTC-PUSCH within the downlink system bandwidth (for example, 5 MHz) corresponding to MTCUE1. Control. The system information acquisition procedure of the mobile station apparatus shown in FIG. 11 can be operated by the control of the data control unit (1).

Also, the data control unit (1) performs control so as to transmit a PRACH random access preamble to the base station apparatus using the PRACH resource region and the RACH sequence information notified from the base station apparatus. The random access procedure shown in FIG. 13 can operate under the control of the data control unit (1).

Also, the data control unit (1) controls the transmission of the mobile station apparatus capability message to which the mobile station apparatus capability signal is added through the mobile station apparatus capability transmission procedure (UE Capability Transfer). The upper layer processing unit (1) includes an ASN encoder, is converted into an information bit string by the ASN encoder process, and, as a mobile station apparatus capability message, for example, information indicating MTC-Capability, that is, movement indicating UE1 or MTCUE1 The station apparatus capability signal is encoded and transmitted to the base station apparatus as the mobile station apparatus capability.

Further, the data control unit (1) monitors the demodulated MTC-PDCCH (4) from the MTCUE1-compatible channel demodulation unit (1) through the paging reception procedure of the mobile station apparatus, and detects the transmission of the paging message. be able to.

In addition, although the case where MTCUE1 performs transmission / reception of an OFDM signal was demonstrated here, this invention is not limited to this, You may transmit MTCUE1 by SC-FDMA system by the function change of a circuit block. Alternatively, transmission may be performed by SC-FDMA (Clustered DFT-S-OFDM or CL-DFT-S-OFDM (Clustered Discrete Fourier Transform Spread OFDM)) method in which the uplink frequency band is not continuous. Further, the configuration of MTCUE1 shown in FIG. 16 may correspond to any of the FDD mode, the TDD mode, or the dual mode of FDD / TDD.

Second embodiment for carrying out the invention

Hereinafter, the second embodiment of the present invention will be described in detail.

As shown in FIG. 11, the system information acquisition procedure in the previous embodiments in MTCUE1 is the same as that in normal UE1 until MTCUE1 receives PBCH and SIB1 (7). The procedure was different. Therefore, in the present embodiment, SIB2 to 13 and MTC-SIB2 to 13 (8) are not transmitted on different PDSCHs, and system information common to UE1 and MTCUE1 and system applied individually to one system information block Including information.

For example, the base station apparatus transmits SIB2 including system information corresponding to MTC-SIB2 applied to MTCUE1. SIB2 is transmitted based on the SIW of SIB1 (7), and is transmitted in the PDSCH within the downlink system bandwidth (for example, 5 MHz) corresponding to MTCUE1 or the resource region of MTC-PDSCH. UE1 which received SIB2 applies the system information common to UE1 and MTCUE1, and the system information applied to UE1. MTCUE1 which received SIB2 applies the system information common to UE1 and MTCUE1, and the system information applied to MTCUE1. The same applies to SIB3 and later.

Further, the base station apparatus may transmit a certain system information block, which is applied only to MTCUE1, using a PDSCH different from the system information block of UE1, or may be included in the system information block of UE1 and transmitted. . For example, the system information of SIB4 may be transmitted separately for SIB4 and MTC-SIB4. In this case, SIB4 is transmitted by the PDSCH of the downlink system bandwidth (for example, 20 MHz) of the base station apparatus, and MTC-SIB4 is transmitted by the PDSCH within the downlink system bandwidth corresponding to MTCUE1 or the resource region of MTC-PDSCH. The

With this configuration, it is possible to make a system configuration in which system information commonly used in SIB2 to 13 and MTC-SIB2 to 13 is not transmitted redundantly. Further, in SIB1 (7), it is not necessary to transmit information of a period (System Information Window: SIW) in which MTC-SIB2 to 13 (8) resources are repeatedly transmitted, so it is necessary to change the reception processing of SIB1 (7) Disappears.

A program that operates on a base station apparatus and a mobile station apparatus related to the present invention is a program (a program that causes a computer to function) that controls a CPU (Central Processing Unit) 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 RAM (Random Access Memory) during the processing, and then stored in various ROMs such as Flash ROM (Read Only Memory) and HDD (Hard Disk Drive). Reading, correction, and writing are performed by the CPU as necessary.

In addition, you may make it implement | achieve the mobile station apparatus in the embodiment mentioned above, and a part of base station apparatus with a computer. In that case, the program for realizing the control function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read by the computer system and executed.

The “computer system” here is a computer system built in the mobile station apparatus or base station apparatus, and includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM or a CD-ROM, and a hard disk incorporated in a computer system.

Furthermore, the “computer-readable recording medium” is a medium that dynamically holds a program for a short time, such as a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line, In such a case, a volatile memory inside a computer system serving as a server or a client may be included and a program that holds a program for a certain time. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

In addition, a part or all of the mobile station device and the base station device in the above-described embodiment may be realized as an LSI that is typically an integrated circuit, or may be realized as a chip set. Each functional block of the mobile station device and the base station device 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, and may be realized by a dedicated circuit or a general-purpose processor. 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.

As described above, the embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the above, and various design changes and the like can be made without departing from the scope of the present invention. It is possible to

1A, 1B, 1C MTC mobile station apparatus 2A, 2B, 2C Mobile station apparatus 3 Base station apparatus

Claims (19)

1. A mobile station device corresponding to machine type communication that communicates with a base station device,
   In the common search area located in the center of the downlink band in the base station apparatus, monitor the physical downlink control channel,
   The mobile station apparatus, wherein the common search area is arranged in a predetermined number of resource blocks based on a downlink bandwidth supported by the mobile station apparatus.
2. The mobile station apparatus according to claim 1, wherein downlink control information accompanied by a random access identifier is monitored in the physical downlink control channel.
3. The mobile station apparatus according to claim 1, wherein downlink control information accompanied by a radio network temporary identifier is monitored in the physical downlink control channel.
4. The mobile station apparatus according to claim 1, wherein paging information is monitored in the physical downlink control channel.
5. A base station device that communicates with a mobile station device that supports machine type communication,
   In the common search area arranged in the center of the downlink band in the base station apparatus, arrange the physical downlink control channel,
   The base station apparatus, wherein the common search area is arranged in a predetermined number of resource blocks based on a downlink bandwidth supported by the mobile station apparatus.
6. The base station apparatus according to claim 5, wherein downlink control information accompanied by a random access identifier is transmitted to the mobile station apparatus in the physical downlink control channel.
7. The base station apparatus according to claim 5, wherein downlink control information accompanied with a radio network temporary identifier is transmitted to the mobile station apparatus in the physical downlink control channel.
8. The base station apparatus according to claim 5, wherein paging information is transmitted to the mobile station apparatus in the physical downlink control channel.
9. A wireless communication system in which a base station apparatus and a mobile station apparatus corresponding to machine type communication communicate with each other,
   The base station device
   In the common search area arranged in the center of the downlink band in the base station apparatus, arrange the physical downlink control channel,
   The mobile station device
   Monitoring the physical downlink control channel;
   The wireless communication system, wherein the common search area is arranged in a predetermined number of resource blocks based on a downlink bandwidth supported by the mobile station apparatus.
10. A mobile station device that communicates with a base station device,
    A mobile station apparatus, wherein a resource defined exclusively for a mobile station apparatus corresponding to machine type communication is allocated by the base station apparatus, and a random access procedure is executed using the resource.
11. The said resource contains the scheduling information regarding the said random access of the mobile station apparatus corresponding to the said machine type communication, or the sequence information regarding the said random access of the mobile station apparatus corresponding to the said machine type communication. The mobile station apparatus as described.
12. The mobile station apparatus according to claim 10 or 11, wherein the resource is allocated to the mobile station apparatus by using the system information block by the base station apparatus.
13. A base station device that communicates with a mobile station device,
    A base station apparatus characterized by allocating a resource defined exclusively for a mobile station apparatus corresponding to machine type communication to the mobile station apparatus, and executing a random access procedure using the resource.
14. The resource includes scheduling information related to the random access of the mobile station apparatus corresponding to the machine type communication or sequence information related to the random access of the mobile station apparatus corresponding to the machine type communication. The base station apparatus as described.
15. The base station apparatus according to claim 13 or 14, wherein the resource is allocated to the mobile station apparatus using a system information block.
16. A wireless communication system in which a base station device and a mobile station device communicate with each other,
    The base station device
    A resource defined exclusively for the mobile station device corresponding to the machine type communication is allocated to the mobile station device;
    The mobile station device
    A wireless communication system, wherein a random access procedure is executed using the resource.
17. A mobile station device corresponding to machine type communication that communicates with a base station device,
    A mobile station apparatus, wherein uplink control information is transmitted to the base station apparatus using a physical uplink control channel arranged only at one end of an uplink band in the base station apparatus.
18. A base station device that communicates with a mobile station device that supports machine type communication,
    A mobile station device, wherein a physical uplink control channel arranged only at one end of an uplink band in the base station device is allocated to the mobile station device.
19. A wireless communication system in which a base station apparatus and a mobile station apparatus corresponding to machine type communication communicate with each other,
    The base station device
    Assigning a physical uplink control channel arranged only at one end of the uplink band in the base station device to the mobile station device,
    The mobile station device
    A radio communication system, wherein uplink control information is transmitted to the base station apparatus using the physical uplink control channel.

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