JP5040665B2 - Mobile communication system - Google Patents

Description

  The present invention relates to a mobile communication system in which a base station performs radio communication with a plurality of mobile terminals, and in particular, mobile communication capable of providing a broadcast type multimedia service (MBMS: Multimedia Broadcast Multicast Service) to mobile terminals. It is about the system.

  Among the communication systems called the third generation, the W-CDMA (Wideband Code division Multiple Access) system has been commercialized in Japan since 2001. Also, by adding a packet transmission channel (HS-DSCH: High Speed-Downlink Shared Channel) to the downlink (dedicated data channel, dedicated control channel), further speeding up data transmission using the downlink Realized HSDPA (High Speed Down Link Packet Access) service has been started. Furthermore, the HSUPA (High Speed Up Link Packet Access) method is also standardized in order to further increase the speed of data transmission in the uplink direction. W-CDMA is a communication method defined by 3GPP (3rd Generation Partnership Project), which is a standardization organization for mobile communication systems, and standardized release 7 editions are compiled.

  In 3GPP, as a communication method different from W-CDMA, “Long Term Evolution LTE” is used for the radio section, and “System Architecture Evolution” (System Architecture Evolution) is used for the entire system configuration including the core network. A new communication method called “Evolution SAE” is being studied. In LTE, the access scheme, radio channel configuration and protocol are completely different from those of the current W-CDMA (HSDPA / HSUPA). For example, while W-CDMA uses Code Division Multiple Access, W-CDMA uses OFDM (Orthogonal Frequency Division Multiplexing) in the downlink direction and SC-FDMA (Single in the uplink direction). Career Frequency Division Multiple Access) is used. The bandwidth is selectable for each base station within 1.4 / 3/5/10/15/20 MHz in LTE, whereas W-CDMA is 5 MHz. Also, LTE does not include circuit switching as in W-CDMA, and is only a packet communication system.

  LTE is defined as an independent radio access network different from the W-CDMA network because the communication system is configured using a new core network different from the W-CDMA core network (GPRS). Therefore, in order to distinguish from a W-CDMA communication system, in an LTE communication system, a base station (Base station) that communicates with a mobile terminal (UE: User Equipment) is an eNB (E-UTRAN NodeB), and a plurality of base stations. A base station controller (Radio Network Controller) that exchanges control data and user data with each other is referred to as EPC (also referred to as Evolved Packet Core, aGW: Access Gateway). In the LTE communication system, a unicast service and an E-MBMS service (Evolved Multimedia Broadcast Multicast Service) are provided. The E-MBMS service is a broadcast-type multimedia service and may be simply referred to as MBMS. Mass broadcast contents such as news, weather forecasts, and mobile broadcasts are transmitted to a plurality of mobile terminals. This is also called a point-to-multipoint service.

  Non-Patent Document 1 describes the current decisions regarding the overall architecture of the LTE system in 3GPP. The overall architecture (Chapter 4 of Non-Patent Document 1) will be described with reference to FIG. FIG. 1 is an explanatory diagram illustrating a configuration of an LTE communication system. In FIG. 1, a control protocol (for example, RRC (Radio Resource Management)) and a user plane (for example, PDCP: Packet Data Convergence Protocol, RLC: Radio Link Control, MAC: Medium Access Control, PHY: Physical layer) for the mobile terminal 101 are based. If terminated at station 102, Evolved Universal Terrestrial Radio Access (E-UTRAN) is composed of one or more base stations 102. The base station 102 performs scheduling (Scheduling) and transmission of a paging signal (also referred to as a paging message or paging message) notified from the MME 103 (Mobility Management Entity). Base stations 102 are connected to each other via an X2 interface. The base station 102 is connected to the EPC (Evolved Packet Core) via the S1 interface. More specifically, the base station 102 is connected to the MME 103 (Mobility Management Entity) via the S1_MME interface, and is connected to the S-GW 104 (Serving Gateway) via the S1_U interface. The The MME 103 distributes the paging signal to a plurality or a single base station 102. Further, the MME 103 performs mobility control (Mobility control) in an idle state. The S-GW 104 transmits / receives user data to / from one or a plurality of base stations 102.

  Non-Patent Document 1 (Chapter 5) describes the current decisions regarding the frame configuration in the LTE system in 3GPP. This will be described with reference to FIG. FIG. 2 is an explanatory diagram showing a configuration of a radio frame used in the LTE communication system. In FIG. 2, one radio frame is 10 ms. The radio frame is divided into 10 equally sized sub-frames. The subframe is divided into two equally sized slots. A downlink synchronization channel (SCH) is included in the first (# 0) and sixth (# 5) subframes for each frame. The synchronization signal includes a first synchronization channel (Primary Synchronization Channel: P-SCH) and a second synchronization channel (Secondary Synchronization Channel: S-SCH). Channels other than MBSFN (Multimedia Broadcast multicast service Single Frequency Network) and channels other than MBSFN are multiplexed on a subframe basis. Hereinafter, a subframe for MBSFN transmission is referred to as an MBSFN sub-frame. Non-Patent Document 2 describes a signaling example at the time of MBSFN subframe allocation. FIG. 3 is an explanatory diagram showing the configuration of the MBSFN frame. In FIG. 3, an MBSFN subframe is allocated for each MBSFN frame (MBSFN frame). A set of MBSFN frames (MBSFN frame Cluster) is scheduled. A repetition period (Repetition Period) of a set of MBSFN frames is assigned.

  Non-Patent Document 1 describes the current decisions regarding the channel configuration in the LTE system in 3GPP. A physical channel (Chapter 5 of Non-Patent Document 1) will be described with reference to FIG. FIG. 4 is an explanatory diagram illustrating physical channels used in the LTE communication system. In FIG. 4, a physical broadcast channel 401 (Physical Broadcast channel: PBCH) is a downlink channel transmitted from the base station 102 to the mobile terminal 101. A BCH transport block is mapped to four subframes in a 40 ms interval. There is no obvious signaling of 40ms timing. A physical control format indicator channel 402 (Physical Control format indicator channel: PCFICH) is transmitted from the base station 102 to the mobile terminal 101. PCFICH notifies base station 102 to mobile terminal 101 about the number of OFDM symbols used for PDCCHs. PCFICH is transmitted for each subframe. A physical downlink control channel 403 (Physical downlink control channel: PDCCH) is a downlink channel transmitted from the base station 102 to the mobile terminal 101. The PDCCH includes resource allocation, HARQ information related to DL-SCH (a downlink shared channel that is one of the transport channels shown in FIG. 5), and PCH (paging that is one of the transport channels shown in FIG. 5). Channel). The PDCCH carries an Uplink Scheduling Grant. The PDCCH carries ACK / Nack that is a response signal for uplink transmission. A physical downlink shared channel 404 (PDSCH) is a downlink channel transmitted from the base station 102 to the mobile terminal 101. On the PDSCH, a DL-SCH (downlink shared channel) that is a transport channel is mapped. A physical multicast channel 405 (Physical multicast channel: PMCH) is a downlink channel transmitted from the base station 102 to the mobile terminal 101. PMCH is mapped with MCH (multicast channel) which is a transport channel.

  A physical uplink control channel 406 (Physical Uplink control channel: PUCCH) is an uplink channel transmitted from the mobile terminal 101 to the base station 102. The PUCCH carries ACK / Nack which is a response signal (response) to downlink transmission. PUCCH carries a CQI (Channel Quality Indicator) report. CQI is quality information indicating the quality of received data or channel quality. A physical uplink shared channel 407 (Physical Uplink shared channel: PUSCH) is an uplink channel transmitted from the mobile terminal 101 to the base station 102. PUSCH is mapped with UL-SCH (uplink shared channel which is one of the transport channels shown in FIG. 5). A physical HARQ indicator channel 408 (Physical Hybrid ARQ indicator channel: PHICH) is a downlink channel transmitted from the base station 102 to the mobile terminal 101. The PHICH carries ACK / Nack that is a response to uplink transmission. A physical random access channel 409 (Physical random access channel: PRACH) is an uplink channel transmitted from the mobile terminal 101 to the base station 102. The PRACH carries a random access preamble.

  A transport channel (Chapter 5 of Non-Patent Document 1) will be described with reference to FIG. FIG. 5 is an explanatory diagram for explaining a transport channel used in an LTE communication system. FIG. 5A shows mapping between the downlink transport channel and the downlink physical channel. FIG. 5B shows mapping between the uplink transport channel and the uplink physical channel. For the downlink transport channel, a broadcast channel (BCH) is broadcast to the entire base station (cell). BCH is mapped to the physical broadcast channel (PBCH). Retransmission control by HARQ (Hybrid ARQ) is applied to the downlink shared channel (DL-SCH). Broadcasting to the entire base station (cell) is possible. Supports dynamic or semi-static resource allocation. Quasi-static resource allocation is also called Persistent Scheduling. Discontinuous reception of the mobile terminal is supported to reduce the power consumption of the mobile terminal. DL-SCH is mapped to a physical downlink shared channel (PDSCH). A paging channel (Paging channel: PCH) supports discontinuous reception of a mobile terminal in order to enable low power consumption of the mobile terminal. Notification to the entire base station (cell) is required. It is mapped to a physical resource such as a physical downlink shared channel (PDSCH) that can be dynamically used for traffic, or a physical resource such as a physical downlink control channel (PDCCH) of another control channel. A multicast channel (Multicast channel: MCH) is used for broadcast to the entire base station (cell). Supports SFN combining of MBMS services (MTCH and MCCH) in multi-cell transmission. Supports quasi-static resource allocation. MCH is mapped to PMCH.

  Retransmission control by HARQ (Hybrid ARQ) is applied to the uplink shared channel (UL-SCH). Supports dynamic or semi-static resource allocation. UL-SCH is mapped to a physical uplink shared channel (PUSCH). The random access channel (Random access channel: RACH) shown in FIG. 5B is limited to control information. There is a risk of collision. The RACH is mapped to a physical random access channel (PRACH). HARQ will be described.

  HARQ is a technique for improving the communication quality of a transmission path by combining automatic repeat request and error correction (forward error correction). There is also an advantage that error correction functions effectively by retransmission even for a transmission path in which communication quality changes. In particular, further quality improvement can be obtained by combining the reception result of the initial transmission and the reception result of the retransmission upon retransmission. An example of the retransmission method will be described. When the reception data cannot be decoded correctly on the receiving side (when a CRC Cyclic Redundancy Check error occurs (CRC = NG)), “Nack” is transmitted from the receiving side to the transmitting side. The transmission side that has received “Nack” retransmits the data. When the reception data can be correctly decoded on the reception side (when no CRC error occurs (CRC = OK)), “Ack” is transmitted from the reception side to the transmission side. The transmitting side that has received “Ack” transmits the next data. An example of the HARQ method is “Chase Combining”. Chase combining is a method in which the same data sequence is transmitted for initial transmission and retransmission, and the gain is improved by combining the initial transmission data sequence and the retransmission data sequence in retransmission. The idea is that even if there is an error in the initial transmission data, it is partially accurate, and it is possible to transmit data with higher accuracy by combining the initial transmission data and the retransmission data of the correct part. Based on. Another example of the HARQ scheme is IR (Incremental Redundancy). IR is to increase the redundancy. By transmitting parity bits in retransmission, the redundancy is increased in combination with the initial transmission, and the quality is improved by the error correction function.

  The logical channel (Chapter 6 of Non-Patent Document 1) will be described with reference to FIG. FIG. 6 is an explanatory diagram illustrating logical channels used in the LTE communication system. FIG. 6A shows mapping between the downlink logical channel and the downlink transport channel. FIG. 6B shows mapping between the uplink logical channel and the uplink transport channel. A broadcast control channel (BCCH) is a downlink channel for broadcast system control information. The BCCH that is a logical channel is mapped to a broadcast channel (BCH) that is a transport channel or a downlink shared channel (DL-SCH). A paging control channel (Paging control channel: PCCH) is a downlink channel for transmitting a paging signal. PCCH is used when the network does not know the cell location of the mobile terminal. The PCCH that is a logical channel is mapped to a paging channel (PCH) that is a transport channel. The common control channel (CCCH) is a channel for transmission control information between the mobile terminal and the base station. CCCH is used when the mobile terminal does not have an RRC connection with the network. Whether the CCCH is provided downstream is not determined at this time. In the uplink direction, the CCCH is mapped to an uplink shared channel (UL-SCH) that is a transport channel.

  A multicast control channel (MCCH) is a downlink channel for one-to-many transmission. This is a channel used for transmission of MBMS control information for one or several MTCHs from the network to the mobile terminal. MCCH is a channel used only for a mobile terminal receiving MBMS. MCCH is mapped to a downlink shared channel (DL-SCH) or multicast channel (MCH) which is a transport channel. The dedicated control channel (Dedicated control channel: DCCH) is a channel for transmitting dedicated control information between the mobile terminal and the network. The DCCH is mapped to the uplink shared channel (UL-SCH) in the uplink, and is mapped to the downlink shared channel (DL-SCH) in the downlink. The dedicated traffic channel (Dedicate Traffic channel: DTCH) is a channel for one-to-one communication to individual mobile terminals for transmission of user information. DTCH exists for both uplink and downlink. The DTCH is mapped to the uplink shared channel (UL-SCH) in the uplink, and is mapped to the downlink shared channel (DL-SCH) in the downlink. A multicast traffic channel (Multicast Traffic channel: MTCH) is a downlink channel for transmitting traffic data from a network to a mobile terminal. MTCH is a channel used only for a mobile terminal that is receiving MBMS. The MTCH is mapped to the downlink shared channel (DL-SCH) or multicast channel (MCH).

  Non-Patent Document 1 describes the current decisions regarding the E-MBMS service in 3GPP. The definition of words related to E-MBMS (Chapter 15 of Non-Patent Document 1) will be described with reference to FIG. FIG. 7 is an explanatory diagram illustrating the relationship between the MBSFN synchronization area and the MBSFN area. In FIG. 7, an MBSFN synchronization area 701 (Multimedia Broadcast multicast service Single Frequency Network Synchronization Area) is an area of a network in which all base stations can synchronize and execute MBSFN (Multimedia Broadcast Multicast Service Single Frequency Network) transmission. That is. The MBSFN synchronization area includes one or more MBSFN areas (MBSFN Areas) 702. In one frequency layer, a base station can belong to only one MBSFN synchronization area. The MBSFN area 702 (MBSFN Area) includes a group of base stations (cells) included in the MBSFN synchronization area of the network. A base station (cell) in the MBSFN synchronization area may constitute a plurality of MBSFN areas.

  The logical structure (Logical Architecture) of E-MBMS will be described with reference to FIG. 8 (Chapter 15 of Non-Patent Document 1). FIG. 8 is an explanatory diagram illustrating a logical structure (Logical Architecture) of E-MBMS. In FIG. 8, a multi-cell / multicast coordination entity (MCE) is a logical entity. The MCE 801 allocates radio resources to all base stations in the MBSFN area in order to perform multi-cell MBMS transmission. In addition to time and / or frequency radio resource allocation, the MCE 801 makes decisions about radio structure details (eg, modulation scheme, code, etc.). The E-MBMS gateway 802 (MBMS GW) is a logical entity. The E-MBMS gateway 802 is located between the eBMSC and the base station, and the main function is to transmit / broadcast the MBMS service to each base station using the SYNC protocol. The M3 interface is a control plane interface between the MCE 801 and the E-MBMS gateway 802. The M2 interface is a control interface between the MCE 801 and the eNB 102. The M1 interface is a user data interface (User Plane Interface) between the E-MBMS gateway 802 and the eNB 102.

  The architecture (Architecture) of E-MBMS (Chapter 15 of Non-Patent Document 1) will be described. FIG. 9 is an explanatory diagram illustrating the architecture of E-MBMS. Two E-MBMS architectures are considered as shown in FIGS. 9A and 9B. The MBMS cell will be described (Non-Patent Document 115). The LTE system includes an MBMS dedicated cell (base station) (MBMS-dedicated cell) and an MBMS / Unicast-mixed cell (MBMS / Unicast-mixed cell) capable of executing both MBMS and unicast services. The MBMS dedicated cell will be described. The characteristics when the MBMS dedicated cell belongs to the frequency layer dedicated to MBMS transmission will be described below. Hereinafter, the MBMS transmission dedicated frequency layer is also referred to as the MBMS dedicated cell frequency layer. Both the downlink logical channels MTCH (multicast traffic channel) and MCCH (multicast control channel) are mapped to the downlink transport channel MCH (multicast channel) or DL-SCH (downlink shared channel) in one-to-many transmission. The There is no uplink in the MBMS dedicated cell. Also, unicast data cannot be transmitted / received within the MBMS dedicated cell. Also, no counting mechanism is set. It is undecided whether to provide paging signals (Paging messages) in the frequency layer dedicated to MBMS transmission.

  Next, the MBMS / unicast mixed cell will be described. The characteristics when the MBMS / unicast mixed cell does not belong to the frequency layer dedicated to MBMS transmission will be described below. A frequency layer other than the MBMS transmission-dedicated frequency layer is referred to as a “unicast / mixed frequency layer”. Both MTCH and MCCH, which are downlink logical channels, are mapped to MCH or DL-SCH, which is a downlink logical channel, in one-to-many transmission. In an MBMS / unicast mixed cell, both unicast data and MBMS data can be transmitted.

  MBMS transmission (Chapter 15 of Non-Patent Document 1) will be described. MBMS transmission in the LTE system supports single-cell transmission (SC transmission) and multi-cell transmission (MC transmission). Single cell transmission does not support SFN (Single Frequency Network) operation. Multi-cell transmission supports SFN operation. MBMS transmission is synchronized in an MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area. SFN combining (Combining) of MBMS services (MTCH and MCCH) in multi-cell transmission is supported. MTCH and MCCH are mapped to MCH by one-to-many transmission. Scheduling is performed by the MCE.

  A multicast control channel (MCCH) structure will be described (Chapter 15 of Non-Patent Document). A broadcast control channel (BCCH) that is a downlink logical channel indicates scheduling of one or two primary multicast control channels (Primary MCCH: P-MCCH). The P-MCCH for single cell transmission is mapped to DL-SCH (downlink shared channel). Further, the P-MCCH for multi-cell transmission is mapped to MCH (multicast channel). When the secondary multicast control channel (Secondary MCCH: S-MCCH) is mapped on the MCH, the primary multicast control channel (P-MCCH) can be used to indicate the address of the secondary multicast control channel (S-MCCH). The broadcast control channel (BCCH) indicates a resource of the primary multicast control channel (P-MCCH), but does not indicate an available service.

  Non-Patent Document 1 (Chapter 10) describes the current decisions regarding paging in 3GPP. The paging group uses the L1 / L2 signaling channel (PDCCH). A clear identifier (UE-ID) of the mobile terminal can be confirmed on the paging channel (PCH).

3GPP TS36.300 V8.2.0

3GPP R1-072963

  The first problem to be solved by the invention will be described. In Non-Patent Document 1, it is not determined whether a paging signal exists in a frequency layer dedicated to MBMS transmission. Therefore, the notification method of the paging signal to the mobile terminal receiving the MBMS service in the frequency layer dedicated to MBMS transmission and the mobile communication system have not been determined. It is an object of the present invention to disclose a paging signal notification method and a mobile communication system for a mobile terminal receiving an MBMS service in a frequency layer dedicated to MBMS transmission.

  A communication system according to the present invention is a communication system that uses an OFDM (Orthogonal Frequency Division Multiplexing) scheme as a downlink access scheme, and uses an SC-FDMA (Single Career Frequency Division Multiple Access) scheme as an uplink access scheme. In a communication system capable of transmitting broadcast type data providing MBMS (Multimedia Broadcast Multicast Service), which is a one-to-many broadcast communication service, and transmitting one-to-one type individual communication data to the mobile terminal. Is a unicast cell that is a cell capable of transmitting / receiving dedicated communication data, a service for both a unicast cell and an MBMS dedicated cell that allows a mobile terminal to receive the broadcast type data but cannot transmit / receive dedicated communication data 3 types of unicast / MBMS mixed cell The MBMS dedicated cell constitutes an MBSFN (Multimedia Broadcast multicast service Single Frequency Network) synchronization area in which a plurality of base stations synchronize and transmit broadcast-type data, and is transmitted from the MBMS dedicated cell. While receiving broadcast-type data, a paging signal for a mobile terminal is transmitted in synchronization in one or a plurality of cells included in the MBSFN synchronization area.

  A communication system according to the present invention is a communication system that uses an OFDM (Orthogonal Frequency Division Multiplexing) scheme as a downlink access scheme, and uses an SC-FDMA (Single Career Frequency Division Multiple Access) scheme as an uplink access scheme. In a communication system capable of transmitting broadcast type data providing MBMS (Multimedia Broadcast Multicast Service), which is a one-to-many broadcast communication service, and transmitting one-to-one type individual communication data to the mobile terminal. Is a unicast cell that is a cell capable of transmitting / receiving dedicated communication data, a service for both a unicast cell and an MBMS dedicated cell that allows a mobile terminal to receive the broadcast type data but cannot transmit / receive dedicated communication data 3 types of unicast / MBMS mixed cell The MBMS dedicated cell constitutes an MBSFN (Multimedia Broadcast multicast service Single Frequency Network) synchronization area in which a plurality of base stations synchronize and transmit broadcast-type data, and is transmitted from the MBMS dedicated cell. Since the paging signal for the mobile terminal is transmitted synchronously in one or a plurality of cells included in the MBSFN synchronization area while receiving the broadcast type data, the paging signal is provided to the mobile terminal provided with the MBMS service from the MBMS transmission dedicated cell. Can be sent.

Embodiment 1 FIG.
In LTE, it is considered that a new MBMS dedicated cell is provided. In the MBMS dedicated cell, a unicast service for performing individual communication addressed to individual terminals is not performed. Therefore, it is difficult to directly apply a method executed in a W-CDMA system that can execute both MBMS and a unicast service in an MBMS dedicated cell, for example, as defined in the Release 6 standard of 3GPP. In order for the mobile terminal to receive paging from the MBMS dedicated cell, it is necessary to provide a new paging channel. The present invention provides a method for a mobile terminal that is receiving or is about to receive an MBMS service in a frequency layer dedicated to MBMS transmission to receive a paging signal from an MBMS dedicated cell. Also disclosed are a channel configuration and mapping method for transmitting a paging signal, and a mobile communication system therefor.

  Hereinafter, a method for placing a paging signal on a physical multicast channel (PMCH) will be disclosed. FIG. 10 is an explanatory diagram showing the configuration of a physical multicast channel provided for each MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area. In FIG. 10, a PMCH to which a multicast control channel (Multicast control channel: MCCH) that is a downlink logical channel and a multicast traffic channel (Multicast Traffic channel: MTCH) are mapped is time-division multiplexed (Time Division) for each MBSFN area 1 to 3. Multiplexing (TDM). In FIG. 10, cell # n1 is a cell in MBSFN area 1, cell # n2 is a cell in MBSFN area 2, and cell # n3 is a cell in MBSFN area 3. Since the cell of the cell # n1 belongs to the MBSFN area 1, the PMCH corresponding to the MBSFN area is transmitted at a certain time. Since PMCH is transmitted in multiple cells (Multi Cell: MC) in the MBSFN area, it is transmitted on the MBSFN subframe. A set of MBSFN frames to which MBSFN subframes are allocated is referred to as an “MBSFN frame cluster” (MBSFN frame cluster). In the MBMS dedicated cell, all subframes in the MBSFN frame may be MBSFN subframes used for multicell transmission. A cycle in which the MBSFN frame cluster is repeated is referred to as an “MBSFN frame cluster repetition period”.

  The MCH of one or a plurality of MBMS transport channels is mapped to the PMCH, and either or both of the MCCH, which is a logical channel of MBMS control information, and the MTCH, which is a logical channel of MBMS data, are mapped to the MCH. To be mapped. MCCH and MTCH may be temporally divided and mapped onto PMCH, or may be further temporally divided and mapped to a physical region that is transmitted in multicell. For example, MBSFN subframes, which are physical areas to which MTCH and MCCH are mapped, may be different. MCCH may be mapped on each MBSFN frame cluster, or only MTCH may be mapped. When only MTCH is mapped onto PMCH, the MCCH repetition period is different from the MBSFN frame cluster repetition period. In some cases, a plurality of MCCHs are mapped on the MBSFN frame cluster. The MCCH repetition period is referred to as an “MCCH repetition period”. In FIG. 10, MCCH1 is MBMS control information for MBSFN area 1, and MTCH1 is MBMS data for MBSFN area 1. Cell # n2 belongs to MBSFN area 2, MCCH2 is MBMS control information for MBSFN area 2, and MTCH2 is MBMS data for MBSFN area 2. Cell # n3 belongs to MBSFN area 3. MCCH3 is MBMS control information for MBSFN area 3, and MTCH3 is MBMS data for MBSFN area 3. The MCCH repetition period may be different for each MBSFN area. The PMCH for each MBSFN area is time-division multiplexed. Therefore, the orthogonality of the cells between the MBSFN areas can be obtained within the MBSFN synchronization area (MBSFN Synchronization Area FIG. 7) in which synchronization between cells is ensured, and interference from cells in other MBSFN areas can be prevented. it can. Since multi-cell transmission is performed in the MBSFN area, cells in each MBSFN area transmit the same data on the same PMCH. Even if one cell belongs to a plurality of MBSFN areas and a plurality of cells are overlapped, the PMCH for each MBSFN area is time-division multiplexed and transmitted on the MBSFN subframe. It is possible to apply while maintaining the orthogonality.

  In a mobile terminal, MBMS can be received by receiving PMCH transmitted in multiple cells from a plurality of cells in the MBSFN area in which the mobile terminal exists, and reception quality is improved by SFN gain by multi-cell transmission. Even in the case where one cell belongs to a plurality of MBSFN areas, the mobile terminal can receive a plurality of MBMS services by receiving the PMCH of each MBSFN area. In addition, since a mobile terminal receiving a PMCH in a desired MBSFN area does not need to receive a PMCH other than the PMCH, discontinuous reception (DRX) can be performed for a time other than the PMCH, which is consumed. Electric power can be reduced. Since the PMCH is continuously transmitted for each MBSFN area and the MBSFN frame is used as the MBSFN frame cluster, the mobile terminal can continuously perform the intermittent reception operation, thereby further reducing the power consumption. It becomes possible.

  FIG. 11 is an explanatory diagram showing a configuration of a physical multicast channel provided for each MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area. In FIG. 10, the PMCH is time division multiplexed (TDM) for each of the MBSFN areas 1 to 3. FIG. 11 shows a case where PMCH is code division multiplexed (CDM) for each of MBSFN areas 1 to 3. Cell # n1 is a cell in MBSFN area 1, cell # n2 is a cell in MBSFN area 2, and cell # n3 is a cell in MBSFN area 3. The PMCH corresponding to MBSFN area 1 is transmitted in the cell of cell # n1. Here, the PMCH may be continuous in time or discontinuous. In the case of discontinuity, the cycle in which the MBSFN frame cluster in which the PMCH corresponding to the MBSFN area is transmitted is repeated becomes an “MBSFN frame cluster repetition period” (MBSFN frame cluster repetition period). In addition, the MBSFN frame cluster repetition period in the case of continuous may be 0 or may not be specified. MCCH and MTCH may be temporally divided and mapped onto PMCH, or may be further temporally divided and mapped to a physical region that is transmitted in multicell. For example, MBSFN subframes that are physical areas to which MTCH and MCCH are mapped as a result may be different. The period in which the MCCH is repeated is referred to as “MCCH repetition period” (MCCH Repetition period). Similarly, a PMCH corresponding to MBSFN area 2 is transmitted in the cell of cell # n2, and a PMCH corresponding to MBSFN area 3 is transmitted in the cell of cell # n3. The MCCH repetition period may be different for each MBSFN area. Since the data multiplied by the spreading code specific to the MBSFN area is mapped to the PMCH for each MBSFN area, interference between MBSFN areas can be suppressed in the MBSFN synchronization area in which synchronization between cells is ensured. Since multi-cell transmission is used in the MBSFN area, cells in each MBSFN area transmit the same data on the same PMCH, that is, data multiplied by a spreading code (Scrambling Code) unique to the MBSFN area. Even if one cell belongs to a plurality of MBSFN areas, the configuration of the PMCH can be applied while suppressing interference between the MBSFN areas.

  The mobile terminal receives the PMCH transmitted from a plurality of cells in the MBSFN area in which the mobile terminal is present, and despreads it with a spreading code unique to the MBSFN area, thereby affecting interference from other MBSFN areas. MBMS can be received while removing reception, and the reception quality can be improved by the SFN gain by multi-cell transmission. Even when one cell belongs to a plurality of MBSFN areas, the mobile terminal receives a PMCH of each MBSFN area and receives a plurality of MBMS services by despreading with a spreading code unique to each MBSFN area. It is possible. In addition, when the PMCH in a desired MBSFN area is not continuous in time, the mobile terminal does not need to receive the time other than the PMCH, so that the intermittent reception operation can be performed at times other than the PMCH, thereby reducing power consumption. It becomes. Even if the PMCH is continuous in time, if there are a plurality of services mapped to the PMCH and the services are temporally multiplexed on the PMCH, the mobile terminal transmits the service to which the desired service is mapped. It is only necessary to receive the time domain within the PMCH, and there is no need to receive other time domains. Therefore, the intermittent reception operation can be performed at other times in the PMCH, and the power consumption can be reduced.

  FIG. 12 is an explanatory diagram showing a configuration of a physical multicast channel (PMCH) carrying a paging signal. FIG. 12 shows the configuration of a physical multicast channel (PMCH) carrying a paging signal. FIG. 12A is a diagram showing a PMCH provided with a paging signal area, which shows that MBMS related information and a paging signal are included on the PMCH. Each of the MBMS related information and the paging signal may exist as an information element in the MTCH and MCCH, or a physical area (resource) to which each is mapped may be time-division multiplexed. FIG. 27 is an explanatory diagram showing a mapping method when MBMS related information and a paging signal are carried as information elements on a multicast control channel (MCCH). Of the MBMS related information, MBMS control information is put on the logical channel MCCH together with the paging signal. MCCH is mapped to a multicast channel (MCH) that is a transport channel together with MTCH, and MCH is mapped to a physical multicast channel (PMCH) that is a physical channel. In this way, it is possible to receive a paging signal when a mobile terminal receiving or trying to receive the MBMS service receives the MCCH.

  Another example will be described. FIG. 28 is an explanatory diagram showing a mapping method when the logical channel PCCH is multiplexed with the logical channels MTCH and MCCH and placed on the transport channel MCH. In FIG. 28, the paging signal is carried on the logical channel PCCH, and the MBMS related information is carried on the MTCH and MCCH. The base station may provide an MTCH-only MBSFN subframe and an MBSFN subframe in which MCCH and PCCH are mapped. Further, control may be performed so as to provide an MCS-only MBSFN subframe and a PCCH-only MBSFN subframe. By doing so, MTCH, MCCH and PCCH, and further, MCCH and PCCH can be transmitted after being divided in time. The mobile terminal only needs to receive the MBSFN subframes of necessary information, and can perform the DRX operation during the MBSFN subframes of unnecessary information. Further, MBSFN subframes carrying MCCH and PCCH may be temporally adjacent. For example, the base station performs scheduling so that an MBSFN subframe on which the PCCH is carried is continuously formed after (or before) the MBSFN subframe on which the MCCH is carried. Since a mobile terminal that is receiving or intending to receive MBMS receives MCCH, MCCH and PCCH reception timing can be known from the MCCH repetition period by making MCCH and PCCH continuous. Therefore, it is possible to continuously receive the paging signal when the mobile terminal receiving or trying to receive the MBMS service receives the MCCH. Also, since no MTCH is inserted between the MCCH and the PCCH, a terminal that has not received the MTCH can receive the PCCH without shifting to the DRX operation. As yet another example, FIG. 29 shows a method using MCH and PCH. FIG. 29 shows a mapping method when the logical channel PCCH is placed on the transport channel PCH, the logical channels MTCH and MCCH are multiplexed and placed on the transport channel MCH, and the PCH and MCH are multiplexed and placed on the physical multicast channel. It is explanatory drawing shown. In FIG. 29, the paging signal is carried on the PCCH, and this PCCH is mapped to the transport channel PCH. This PCH is multiplexed with MCH and mapped to PMCH. In this way, the base station can transmit the PCH and MCH by dividing them in time, and further can perform encoding separately. Therefore, the mobile terminal can perform decoding separately at the time of reception.

  All cells in a certain MBSFN area periodically perform multi-cell transmission in the MCCH repetition period with the MCCH corresponding to the MBSFN area on the PMCH. A mobile terminal that is receiving or intending to receive an MBMS service transmitted in a multi-cell manner from a cell in the MBSFN area periodically receives the MCCH and receives the contents of the MBMS service, the frame configuration, etc. Enable service reception. Accordingly, by including a paging signal in the MCCH as disclosed in FIG. 27, a mobile terminal receiving or attempting to receive the MBMS service can receive the paging signal when receiving the MCCH. it can. This eliminates the need for the mobile terminal to separately receive paging at a timing other than receiving the MCCH, and thus enables paging to be received without interrupting reception of the MBMS service. In addition, intermittent reception operation can be performed during the time when the MCCH is not received and the time when the MBMS service is not received, and the power consumption of the mobile terminal can be reduced.

  In the case of the mapping method disclosed in FIG. 28, MCCH and PCCH may be configured in the same MBSFN subframe, or an MBSFN subframe in which MCCH is carried and an MBSFN subframe in which a paging signal is carried are temporally arranged. It may be divided and further adjacent. As a feature of the present invention, there is “so that PCCH can be seen when viewing MCCH”. Therefore, if MCCH and PCCH are in the same MBSFN subframe, the subframe may be received. However, if the MBSFN subframe on which MCCH is carried and the subframe on which PCCH is carried are time-divided, they should be adjacent to each other. Is preferred. In the case of the mapping method disclosed in FIG. 29, the MBSFN subframe carrying the MCCH and the MBSFN subframe carrying the paging signal may be temporally adjacent. For example, the base station performs scheduling so that an MBSFN subframe on which the PCCH is carried is continuously formed after (or before) the MBSFN subframe on which the MCCH is carried. With this configuration, it is possible to continuously receive a paging signal when a mobile terminal that is receiving or intending to receive an MBMS service receives an MCCH. This eliminates the need for the mobile terminal to receive a separate paging signal at a timing other than receiving a subframe carrying MCCH and PCCH, and thus enables the mobile terminal to receive the paging signal without interrupting reception of the MBMS service. In addition, intermittent reception operation can be performed during the time when the MCCH is not received and the time when the MBMS service is not received, and the power consumption of the mobile terminal can be reduced.

  FIG. 12B discloses a configuration in which an indicator indicating whether MBMS control information has been changed and an indicator indicating whether a paging signal has been transmitted are provided. Either of these indicators may be provided, or both of them may be provided. An indicator indicating whether the MBMS control information has been changed is referred to as an “MBMS related information change presence / absence indicator”, and an indicator indicating whether a paging signal has been transmitted is referred to as a “paging signal presence indicator”. The physical area to which the indicator is mapped may be provided in the MBSFN subframe in which the PMCH is transmitted, or may be provided in the physical area temporally adjacent to the MBSFN subframe in which the PMCH is transmitted. By doing so, the mobile terminal can receive and decode the MCCH and the paging signal on the PMCH immediately after receiving the indicator. For example, 1-bit information is used as an indicator. Each indicator is multiplied by a spreading code unique to the MBSFN area and is mapped to a predetermined physical area. As another method, for example, each indicator may be composed of a sequence specific to the MBSFN area and mapped to a predetermined physical area. When the mobile terminal receives an incoming call, the paging signal presence / absence indicator is set to “1”, and when there is no incoming call, the paging signal presence / absence indicator is set to “0”. Also, for example, when the MBMS control information on the MCCH is changed due to a change in the content of the MBMS service transmitted in the MBSFN area, the MBMS related information change presence / absence indicator is set to “1”. A period (MBMS modification period) in which MBMS related information can be changed is determined, and a change presence / absence indicator “1” is repeatedly transmitted within the period. The period (MBMS modification period), start timing (SFN, starting point), etc. may be determined in advance, or may be notified by broadcast information from a serving cell in a unicast service or from an MBMS dedicated cell. If there is no further change in the MBMS related information after the period has elapsed, the MBMS related information change presence / absence indicator is set to “0”.

  The mobile terminal receives the indicator in the MBSFN subframe in which the PMCH in the desired MBSFN area is transmitted by multi-cell or adjacent MBSFN subframe, performs despreading, etc., and determines whether the indicator is 1 or 0, thereby It is possible to determine whether there has been a change in the MBMS control information existing in the, and whether there is a paging signal. By providing the indicator in this manner, when there is no change in the MBMS control information or when there is no paging signal, the mobile terminal does not need to receive or / and decode the entire PMCH information. For this reason, it is possible to reduce the reception power of the mobile terminal. The physical area to which the MBMS-related information change presence / absence indicator indicating whether the MBMS control information has been changed may be the first MBSFN subframe of one or more MBSFN subframes to which the MBMS control information is mapped. Furthermore, it may be an OFDM (Orthogonal Frequency Division Multiplexing) symbol at the head of the first MBSFN subframe. Accordingly, the mobile terminal can determine whether the MBMS control information has changed by receiving the first OFDM symbol.

  Further, a physical area to which a paging signal presence / absence indicator indicating whether or not a paging signal is present may be used as the first MBSFN subframe of one or a plurality of MBSFN subframes to which the paging signal is mapped. Further, it may be the first OFDM symbol of the first MBSFN subframe. As a result, the mobile terminal can determine whether a paging signal exists by receiving the first OFDM symbol. By mapping each indicator to the physical area as described above, when there is no MBMS control signal change, when there is no paging information, it is not necessary to receive or / and decode each subsequent OFDM symbol. It is possible to reduce received power. In addition, since it can be determined early with the first MBSFN subframe or the first OFDM symbol, the MBMS control information can be received immediately or the paging signal can be received immediately. Control delay can be reduced. As an indicator, the MBMS-related information change presence / absence indicator and the paging signal presence / absence indicator may be mapped to the same physical area, or may be mapped to different physical areas. When mapping to the same physical area, an OR operation of each indicator may be taken. As a result, since the mobile terminal needs only one indicator to receive, the effect of simplifying the receiving circuit configuration can be obtained. In the case of mapping to different physical areas, this allows the mobile terminal to receive only the necessary indicators and eliminates the need to receive other indicators. Therefore, it is possible to further reduce the reception power of the mobile terminal and further reduce the reception delay of necessary information. For example, a mobile terminal that has received an MBMS service but is set not to receive a paging signal need only receive an MBMS-related information change presence / absence indicator, eliminating the need to receive a paging signal presence / absence indicator. Can do. The repetition period of each indicator may be the same or different. The repetition period of each indicator may be the same as or different from the repetition period of MCCH. For example, an MBMS-related information change presence / absence indicator may be provided on the PMCH on which the MCCH is carried once every several times.

  The repetition period of the indicator is a paging signal presence / absence indicator repetition period (Repetition period) and an MBMS-related change presence / absence indicator repetition period (Repetition period), respectively. The start timing (SFN, starting point) of the MBSFN subframe in which the indicator exists, the subframe number, the repetition period of each indicator, etc. may be notified by the broadcast information of the serving cell of the unicast service, or the broadcast of the MBMS dedicated cell It may be notified by information or may be determined in advance. The channel dedicated to the MBMS-related information change presence / absence indicator may be, for example, a MICH (MBMS Indicating CHannel), and a paging signal presence / absence indicator may be configured in the MICH. The repetition period of the paging signal presence / absence indicator may be the same as or different from the MICH repetition period (MICH Repitition period). The notification of the indicator can be performed by the same method as described above. Thereby, the time when each indicator is transmitted is not limited to the time when MCCH is transmitted, and the system can be designed flexibly.

  When the paging signal is included in the PMCH, there is a problem that it takes too much time to detect the paging signal addressed to the own mobile terminal when the number of mobile terminals that have received an incoming call becomes enormous. Further, there arises a problem that an area for mapping paging signals of all mobile terminals that have received incoming calls cannot be secured in a predetermined physical area carrying a paging signal. In order to solve these problems, a paging grouping method is disclosed. FIG. 12C shows a paging grouping method. All mobile terminals are divided into K groups, and a paging signal presence / absence indicator is provided for each group. The physical area for the paging signal presence / absence indicator is divided into K pieces, and the paging signal presence / absence indicator of each group is mapped to each of the divided physical areas. Here, K can take from 1 to the value of the total number of mobile terminals. When an incoming call is received at a certain mobile terminal, the paging signal presence / absence indicator of the group to which the mobile terminal belongs is set to “1”. When all mobile terminals belonging to a certain group do not receive an incoming call, the paging signal presence / absence indicator of that group is set to “0”. The paging signal presence / absence indicator may be subjected to repetition or the like in order to satisfy a desired reception error rate at the mobile terminal. The physical area to which the paging signal is mapped is also divided into K pieces so as to correspond to the K groups. The paging signal may be an identifier (identification number, identification code) for each mobile terminal. One physical area divided into K is a physical area in which paging signal data required by one mobile terminal is accommodated by adding the number of mobile terminals in the group. The number of mobile terminals in a group may be the same in all groups, or may be different for each group. For example, the number of mobile terminals in the group may be an average value of the number of mobile terminals that simultaneously receive incoming calls. Alternatively, the number of mobile terminals that can be assigned to one OFDM symbol may be used, and each OFDM symbol may be associated with each group. When an incoming call is received at a certain mobile terminal, the paging signal presence / absence indicator of the group to which the mobile terminal belongs is set to “1” and mapped to the paging signal presence / absence indicator physical area corresponding to the group. At the same time, the paging signal for the mobile terminal that has received the incoming call is mapped to the physical area of the paging signal corresponding to the group to which the mobile terminal belongs. The mapping of the paging signal to the physical area is performed by multiplying each mobile terminal by an identification code unique to the mobile terminal. When the paging signal is an identifier for each mobile terminal, the control for multiplying the mobile terminal specific identification code can be omitted.

  The mobile terminal receives the paging signal presence / absence indicator of the group to which the mobile terminal belongs to determine whether an incoming call has been made to the group to which the mobile terminal belongs. When it is determined that an incoming call is received, a physical area to which a paging signal associated with a group to which the mobile terminal belongs is received and decoded (Decode). After decoding processing, blind detection is performed by performing correlation calculation with an identification code unique to the mobile terminal, and it is possible to determine that there is an incoming call to the mobile terminal by specifying a paging signal for the mobile terminal. It becomes. If no paging signal for the mobile terminal is detected, it is determined that there is no incoming call to the mobile terminal. By grouping the mobile terminals into K groups, the mobile terminal does not need to receive the entire paging signal area, and only receives the necessary area, that is, only the physical area to which the group to which the mobile terminal belongs corresponds. Therefore, the paging signal detection time at the mobile terminal can be shortened, and further, it is not necessary to receive the corresponding physical area of the group to which the mobile terminal does not belong, so that the reception power of the mobile terminal can be reduced. Furthermore, by using a paging signal presence / absence indicator corresponding to each group, a paging signal presence / absence indicator can be provided with few physical resources even when there are a large number of mobile terminals. Furthermore, the mobile terminal only needs to receive the paging signal area as needed, and it is possible to reduce the reception power of the mobile terminal, and when it is not necessary to receive the paging signal, the mobile terminal immediately moves to the next operation. Therefore, the control delay can be reduced.

  In the above-described embodiment, one physical area divided into K pieces for mapping the paging signal is obtained by adding the physical area in which the paging signal data required by one mobile terminal is accommodated by the number of mobile terminals in the group. It was in the physical area. However, when the number of mobile terminals increases, the required physical area increases, and the overhead for transmitting the MBMS service increases, so the transmission speed of MBMS service data decreases. In order to prevent this, the paging signal for the mobile terminal is multiplied by an identification code unique to the mobile terminal for each mobile terminal. As a result, the mobile terminal can blindly detect whether the information is addressed to its own mobile terminal using an identification code unique to the mobile terminal, so that the physical area for mapping the paging signal for each mobile terminal is fixed in advance. There is no need to keep it. Therefore, a physical area for paging signals for all mobile terminals is not required, and it is sufficient if there is an area for the number of mobile terminals that are expected to actually receive incoming calls. As an example, there is a method in which the number of mobile terminals in the group is an average value of the number of mobile terminals that receive incoming calls simultaneously. This method makes it possible to effectively use limited physical resources. In addition, by using the above method, even when the number of mobile terminals receiving more than expected is increased, it becomes possible to transmit a paging signal to a new incoming mobile terminal on the next PMCH, etc. It becomes possible to respond flexibly by scheduling at the base station.

  When the total number of mobile terminals is small, only the paging signal presence / absence indicator may be transmitted with the value of K as the total number of mobile terminals. In this case, it is not necessary to secure a paging-related physical area, and it is sufficient to secure physical areas for paging signal presence / absence indicators for the number of all mobile terminals. For this reason, the efficiency of radio resources can be improved. In this case, a physical area for a paging signal presence / absence indicator corresponding to each mobile terminal exists. For this reason, in the mobile terminal, it is possible to determine the presence / absence of an incoming call without receiving the paging signal area only by receiving and decoding the physical area for the paging signal presence / absence indicator corresponding to the mobile terminal. The control delay in the paging operation can be reduced.

  FIG. 13 is an explanatory diagram showing a method for mapping a paging signal to an area on a physical multicast channel. In FIG. 13, a paging signal for mobile terminals n1, n2, etc. that has received an incoming call such as a voice call among mobile terminals belonging to paging group n is mapped to a physical area for group n. The base station multiplies the paging signal of each mobile terminal by an identification code (number, sequence) unique to the mobile terminal, adds CRC (Cyclic Redundancy Check), and performs processing such as encoding (Encode) and rate matching . The result of performing a series of these processes is assigned to each control information element (CCE: Control Channel Element) corresponding to the size of the physical area to be mapped, and connected to each mobile terminal that has received an incoming call. The concatenated result is subjected to spreading processing, modulation processing, etc., using a spreading code (Scrambling code) unique to the MBSFN area. The modulation process may be specific to the MBSFN area. The result of performing these processes is mapped to the physical area corresponding to the paging group n. At this time, the base station sets “1” to the paging signal presence / absence indicator of the paging group n and maps it to the physical area of the paging group n of the paging signal presence / absence indicator.

  The physical area corresponding to the paging group n may be determined in advance, or may be notified as broadcast information from the unicast-side serving cell or the MBMS dedicated cell. The mobile terminal receives the paging signal presence / absence indicator of the paging group to which the mobile terminal belongs, and if it is “1”, receives the paging signal physical area corresponding to the paging group. The paging signal physical area is received, demodulated, and despread by a spreading code unique to the MBSFN area, and the result is divided into control information element units. A process such as decoding (Decode) is performed for each divided control information element unit, and a correlation calculation is performed using an identification number unique to the mobile terminal, thereby blindly detecting a paging signal for the mobile terminal. If the correlation calculation result is greater than a certain threshold, it is determined that there is paging for the mobile terminal, and a paging incoming operation is started by a paging signal. If it is less than a certain threshold value, it is determined that there is no paging for the terminal itself, and the process shifts to reception of MBMS related information, or shifts to the intermittent reception operation if it is not necessary to receive MBMS related information. Which group the own mobile terminal belongs to may be derived by a predetermined calculation method, or may be notified from a higher layer as a broadcast information from a serving cell or MBMS dedicated cell of unicast service.

  FIG. 14 shows another example of a method for mapping a paging signal to a physical area carrying a paging signal on the PMCH. Among the mobile terminals belonging to the paging group n, the paging signal is mapped to the physical area for the group n for the mobile terminals n1, n2, etc. that are receiving calls. The base station adds CRC to the paging signal of each mobile terminal and performs processing such as encoding and rate matching. The results of these processes are multiplied by an identification code (number) unique to the mobile terminal. The orthogonality is obtained between the mobile terminals by using an identification code unique to the mobile terminal as a spreading code having orthogonality. The base station multiplexes the result of multiplying the spreading code for each mobile terminal that is receiving an incoming call. The multiplexed result is subjected to spreading processing, modulation processing, etc. using a spreading code unique to the MBSFN area. The modulation process may be specific to the MBSFN area. The result of performing these processes is mapped to the physical area corresponding to the paging group n. At this time, the base station sets “1” to the paging signal presence / absence indicator of the paging group n and maps it to the physical area of the paging group n of the paging signal presence / absence indicator. The physical area corresponding to the paging group n may be determined in advance, or may be notified as broadcast information from the unicast-side serving cell or the MBMS dedicated cell. The mobile terminal receives the paging signal presence / absence indicator of the paging group to which the mobile terminal belongs, and if it is “1”, receives the paging signal physical area corresponding to the paging group. The paging signal physical area is received, demodulated, and despread by a spreading code unique to the MBSFN area. By performing a correlation operation on the result using an identification number unique to the mobile terminal, a paging signal for the mobile terminal is blind-detected. When the correlation calculation result is larger than a certain threshold value, it is determined that there is paging for the mobile terminal, and the paging incoming operation is started by the paging signal after decoding. If it is less than a certain threshold value, it is determined that there is no paging for the terminal itself, and the process shifts to reception of MBMS related information, or shifts to the intermittent reception operation if it is not necessary to receive MBMS related information. Which group the own mobile terminal belongs to may be derived by a predetermined calculation method, or may be notified from a higher layer as a broadcast information from a serving cell or MBMS dedicated cell of unicast service. Note that the paging signal described in FIGS. 13 and 14 may be a transport channel to which the paging signal is mapped. This can be applied to the following embodiments. Any information that carries a paging signal, which is paging-related information required when the mobile terminal receives paging, may be used.

  Several methods for mapping the paging signal to the physical area carrying the paging signal of the PMCH have been disclosed. However, the mapping to the physical area carrying the paging signal may be an arbitrary predetermined area or a localized area. It may be mapped to (physical region continuous on the frequency axis) or may be mapped to distributed (physical region distributed on the frequency axis).

  In the above example, the paging signal is multiplied by an identification number or spreading code unique to the mobile terminal. By adopting such a configuration, when the information amount of the paging signal is the same in each mobile terminal, the control information element unit to be allocated by making the processing such as encoding (encode) and rate matching the same between the mobile terminals It is possible to make the sizes of the regions of the same. Therefore, since the size of the area of the control information element unit for blind detection in the mobile terminal is limited to one, the number of blind detections can be reduced and the detection time can be shortened. Therefore, it is possible to obtain an effect that the circuit configuration of the mobile terminal, power consumption, and control delay can be reduced.

  As described above, the mobile terminal receives the entire paging signal area by multiplying the paging signal by the identification number or spreading code unique to the mobile terminal and mapping it to the physical area where the PMCH paging signal is carried for each paging group. Since it is only necessary to receive only the necessary area, that is, only the physical area corresponding to the group to which the mobile terminal belongs, the paging signal detection time at the mobile terminal can be shortened, and the time mobile terminal does not belong Since it is not necessary to receive the physical area corresponding to the group, the reception power of the mobile terminal can be reduced. Furthermore, a paging signal presence / absence indicator corresponding to each group can be used, and even when there are a large number of mobile terminals, the paging signal presence / absence indicator can be provided with few physical resources. Furthermore, the mobile terminal only needs to receive the paging signal area as needed, and it is possible to reduce the reception power of the mobile terminal, and when it is not necessary to receive the paging signal, the mobile terminal immediately moves to the next operation. Therefore, the control delay can be reduced. Furthermore, since the mobile terminal can blindly detect whether the information is addressed to the mobile terminal by using an identification code or a spreading code unique to the mobile terminal, a physical area for mapping a paging signal for each mobile terminal Since there is no need to have a fixed paging signal area for all mobile terminals, there is no need for a physical area for paging signals for all mobile terminals, and there is only an area for the number of mobile terminals that are expected to actually receive calls. It is possible to effectively use physical resources. Furthermore, even if the number of mobile terminals that receive more than expected is increased, a paging signal to a new incoming mobile terminal can be transmitted on the PMCH carrying the next MCCH. It is possible to respond flexibly by scheduling.

  In the above example, the base station multiplies the paging signal by the identification number unique to the mobile terminal. However, it is also possible to use a method of multiplying CRC instead of a paging signal by an identification number unique to the mobile terminal. The method of multiplying the CRC by the identification number unique to the mobile terminal is effective when the information amount of the paging signal of each mobile terminal is different.

  By adopting the method for placing a paging signal on the PMCH disclosed in the first embodiment, the paging signal of all the mobile terminals that are receiving or trying to receive the MBMS service from the MBMS dedicated cell as the mobile communication system And the mobile terminal can receive a paging signal from the MBMS dedicated cell.

  Hereinafter, a modification of the first embodiment will be described. In Embodiment 1, in order to receive a paging signal from an MBMS dedicated cell, a method of placing a paging signal on the PMCH for each MBSFN area has been disclosed. As a configuration of PMCH, a method of time division multiplexing (TDM) for each MBSFN area and code division multiplexing (CDM) for each MBSFN area has been disclosed. In a first modification described below, a method of mixing time division multiplexing (TDM) and code division multiplexing (CDM) for each MBSFN area is disclosed as the PMCH configuration.

  FIG. 15 is an explanatory diagram showing the configuration of the PMCH provided for each MBSFN area. In FIG. 15, both time division multiplexing (TDM) and code division multiplexing (CDM) are used for each MBSFN area. Cell # n1 is a cell in MBSFN area 1, cell # n2 is a cell in MBSFN area 2, and cell # n3 is a cell in MBSFN area 3. The cells of cell # 1, cell # 2, and cell # 3 are also cells in the MBSFN area 4. The PMCHs in MBSFN areas 1, 2, and 3 are code division multiplexed, and the PMCHs in MBSFN areas 1, 2, and 3 and the PMCH in MBSFN area 4 are time division multiplexed. Since the cell of the cell # n1 belongs to the MBSFN area 1, the PMCH corresponding to the MBSFN area 1 is transmitted at a certain time. Since PMCH is transmitted by multicell in the MBSFN area, it is transmitted on the MBSFN subframe. A set of MBSFN frames to which MBSFN subframes are allocated is referred to as an “MBSFN frame cluster” (MBSFN frame cluster). In the MBMS dedicated cell, all subframes in the MBSFN frame may be MBSFN subframes used for multicell transmission. A period in which an MBSFN frame cluster corresponding to an MBSFN area is repeated is referred to as an “MBSFN frame cluster repetition period”. The MBCH transport channel MCH is mapped to the PMCH, and either or both of the logical channel MCCH of the MBMS control information and the logical channel MTCH of the MBMS data are mapped to the MCH.

  MCCH and MTCH may be temporally divided and mapped onto PMCH, or may be further temporally divided and mapped to a physical region that is transmitted in multicell. For example, MBSFN subframes that are physical areas to which MTCH and MCCH are mapped as a result may be different. MCCH may be mapped on each MBSFN frame cluster or only MTCH. When only MTCH exists, the MCCH repetition period is different from the MBSFN frame cluster repetition period. In some cases, a plurality of MCCHs are mapped on the MBSFN frame cluster. The MCCH repetition period is referred to as an “MCCH repetition period”. In FIG. 15, MCCH1 is MBMS control information for MBSFN area 1, and MTCH1 is MBMS data for MBSFN area 1. Similarly, MCCH2 is MBMS control information for MBSFN area 2, MTCH2 is MBMS data for MBSFN area 2, MCCH3 is MBMS control information for MBSFN area 3, and MTCH3 is MBMS data for MBSFN area 3. The PMCHs of cell # n1, cell # n2, and cell # n3 are code division multiplexed and transmitted at the same timing. Since the cells of cell # n1 (cell # n2, cell # n3) belong to MBSFN area 1 (2, 3) and MBSFN area 4, the PMCH of MBSFN area 1 (2, 3) and the PMCH of MBSFN area 4 are time-shared. Is multiplexed. Since the PMCH in the MBSFN area 4 is transmitted by multicell transmission in the MBSFN area 4, the PMCH transmission timings are all the same in the cells # n1, # n2, and # n3. In this way, by mixing the time division multiplexing and code division multiplexing for the PMCH for each MBSFN area, for example, time division multiplexing is performed for MBSFN areas that overlap between MBSFN areas, and code division multiplexing is performed for non-overlapping MBSFN areas. Can be used. Therefore, since code division multiplexing is used compared to the case of only time division multiplexing, the efficiency of radio resources can be improved. Furthermore, compared with the case of only code division multiplexing, it is possible to reduce mutual interference between overlapping MBSFN areas, and it is possible to reduce reception errors of MBMS data at the mobile terminal.

  Next, the configuration of each PMCH for the mobile terminal to receive paging from the MBMS dedicated cell will be described. Time division multiplexing and code division multiplexing are mixed for each MBSFN area. Accordingly, there are a plurality of PMCHs for each MBSFN area transmitted from each cell. Thus, in order to cope with the case where there are a plurality of PMCHs for each MBSFN area in a certain cell, a paging signal is placed on the PMCHs corresponding to all MBSFN areas. A method of including a paging signal as shown in FIG. 12 can be applied to the PMCH in each MBSFN area. With this configuration, a mobile terminal in an area capable of receiving MBMS services in a plurality of MBSFN areas receives the MCCH of any one MBSFN area that is receiving or is about to receive the MBMS service. Thus, paging can be received when the MCCH is received. The mobile terminal does not need to receive MCCH in an MBSFN area different from the MBMS service being received, and intermittent reception is possible, so that power consumption can be reduced. As another method, a configuration on the PMCH of one MBSFN area will be described. For example, MCCH (P-MCCH) is mapped only to the PMCH of the smallest MBSFN area to which a certain cell belongs, and the MCCH is not mapped to the PMCH of other MBSFN areas, and the PMCH of the smallest MBSFN area is mapped. Applies a method of putting a paging signal as shown in FIG. The MBMS control information of other MBSFN areas is included in the MCCH (P-MCCH) mapped to the PMCH of the smallest MBSFN area.

  By adopting such a configuration, for example, even if the mobile terminal receives the MBMS service of any MBSFN area, the MCCH (P-MCCH) of the smallest MBSFN area is received. Paging can be received when receiving (P-MCCH). Furthermore, the mobile terminal does not need to change the paging reception period, here, the MCCH repetition period (MCCH repetition period) in accordance with the change of the MBMS service to be received, and can simplify the control. Furthermore, since only MTCH can be mapped to PMCHs in other MBSFN areas, an effect that the efficiency of radio resources can be achieved as a system is obtained. As another method, the MCCH corresponding to another MBSFN area may be mapped to the PMCH of the smallest MBSFN area. In this case as well, a method of putting a paging signal as shown in FIG. 12 can be applied to the PMCH. Thereby, the same effect can be obtained, and each MCCH can be time-divided and mapped to the physical area. Therefore, the mobile terminal can receive the MCCH of a desired MBSFN area, and can receive intermittently the other physical area in which the MCCH is transmitted. As still another method, a configuration for placing on the PMCH of one MBSFN area will be described. For example, the primary MCCH (P-MCCH) is mapped to the PMCH of the MBSFN area to which a certain cell belongs, and the secondary MCCH (S-MCCH) is mapped to the PMCH of other MBSFN areas. A method of including a paging signal as shown in FIG. With such a configuration, for example, even if a mobile terminal receives an MBMS service in any of a plurality of MBSFN areas, by receiving the P-MCCH, paging is performed when the P-MCCH is received. It becomes possible to receive. Furthermore, the mobile terminal does not need to change the paging reception period, here, the MCCH repetition period (MCCH repetition period) in accordance with the change of the MBMS service to be received, and can simplify the control. The method disclosed in FIG. 13 and FIG. 14 can be applied to the method for mapping the paging signal to the physical area carrying the paging signal on the PMCH.

  In the first embodiment and the modification, the case where there are a plurality of cells in the MBSFN area is shown. However, the present invention is applicable even if there is only one cell in the MBSFN area. In the one cell, it is possible to apply the method of mapping the paging signal disclosed in FIG. 13 to the physical area carrying the paging signal on the PMCH, with the configuration of the PMCH disclosed in FIG. In the case of only one cell, even though transmission using PMCH, the SFN gain associated with normal multi-cell transmission cannot be obtained, but the MBMS service can be limited to a narrow area, and so-called spot service can be provided. Become. Further, there may be only one cell in the MBSFN area, and the MBMS service data corresponding to the MBSFN area is not transmitted in the one cell, and only the MBMS control information is transmitted. In this case, only the MCCH is mapped without mapping the MTCH on the PMCH. The MCCH may include MBMS control information (MCCH) of another MBSFN area to which the one cell belongs. This eliminates the need to map each MCCH to PMCHs in other MBSFN areas, thereby improving the efficiency of radio resources. Furthermore, since the mobile terminal receives only the MCCH corresponding to the MBSFN area, it can receive all the MCCHs of one or more MBSFN areas that can be received without receiving other PMCHs. Control delay time when receiving the MBMS service can be reduced. Furthermore, when it is not necessary to receive MBMS service information of other MBSFN areas, an intermittent reception operation becomes possible, and the reception power can be reduced.

Embodiment 2. FIG.
Since the mobile terminal receives paging from an MBMS dedicated cell that does not support the unicast service, in the first embodiment, paging is performed on a physical multicast channel (PMCH) for each MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area. A method for placing a signal has been disclosed. In the second embodiment, a method for providing a paging-dedicated physical channel for multi-cell transmission in the MBSFN area and placing a paging signal on the physical channel is disclosed.

  FIG. 16 is an explanatory diagram showing a configuration of a paging-dedicated physical channel that is transmitted by multicell in the MBSFN area. In a certain cell, a part of the MBSFN subframe corresponding to the MBSFN area to which the cell belongs is defined as a dedicated physical channel (DPCH) for paging, and a DPCH is provided for each subframe. As shown in the first embodiment, since the unicast service is not supported in the MBMS dedicated channel, all subframes of the MBSFN frame may be MBSFN subframes. As an example, FIG. 30 shows a method of mapping a paging signal to a physical channel dedicated to paging. FIG. 30 shows a mapping method when the logical channel PCCH including the paging signal is put on the transport channel PCH, the logical channels MTCH and MCCH are multiplexed and put on the transport channel MCH, and the PCH is put on the physical channel dedicated to paging. It is explanatory drawing shown. The logical channel PCCH carrying the paging signal is mapped to the transport channel PCH and mapped to the DPCH, which is a physical channel dedicated to paging. On the other hand, as usual, MBMS related information is carried on logical channels MTCH and MCCH, which are mapped to transport channel MCH and mapped to physical channel PMCH. The DPCH is configured to be transmitted by multicell in the MBSFN area, and DPCH and PMCH are multiplexed and transmitted in the same MBSFN subframe.

  When the PMCH configuration for each MBSFN area is, for example, code division multiplexed as shown in FIG. 11, the PMCH is transmitted in consecutive MBSFN subframes. In this case, DPCH can be provided in all subframes on the time axis. Therefore, compared with Embodiment 1, the frequency | count that a paging signal can be transmitted increases. In this way, a part of each subframe of the MBSFN subframe transmitted in multi-cells in the MBSFN area is used as a DPCH for paging signal transmission, so that the frequency of paging signal transmission can be increased as a system, and the MBMS dedicated cell The number of mobile terminals that enable paging can be increased. Furthermore, when paging to a mobile terminal capable of paging can be avoided, a shortage of paging area can be avoided, so that the paging information transmission delay time can be shortened. The above example describes the case where the PMCH configuration for each MBSFN area is code division multiplexing (CDM). However, in the case of time division multiplexing (TDM) or when both time division multiplexing and code division multiplexing are applied, a certain cell is used. The DPCH may be provided in all MBSFN subframes to which PMCHs corresponding to one or a plurality of MBSFN areas to which the UE belongs are transmitted. Thereby, compared with Embodiment 1, since the frequency | count that a paging signal can be transmitted can be increased, the same effect can be acquired.

  FIG. 17 is an explanatory diagram showing the configuration of the MBSFN subframe. In FIG. 17, DPCH and PMCH are time-division multiplexed in the MBSFN subframe. A paging signal is mapped to DPCH, and MBMS related information is mapped to PMCH. By separating the physical channels to which each is mapped, the paging signal and the MBMS-related information can be encoded separately in the base station, and decoding can be performed separately in reception at the mobile station. In addition, the physical area can be time division multiplexed, the mobile terminal that has not received the MBMS service and has received only the paging information does not need to receive the PMCH, while the PMCH is being transmitted. Is capable of discontinuous reception, thereby reducing the power consumption of the mobile terminal. On the other hand, mobile terminals that do not need to receive paging information do not need to receive DPCH, and can perform intermittent reception operations while DPCH is transmitted, thereby reducing power consumption of the mobile terminal. It becomes possible. The DPCH is transmitted in kOFDM symbols of each MBSFN subframe. The value of k may be determined in advance or may be notified by broadcast information of the MBMS dedicated cell. Moreover, you may notify by the alerting | reporting information of a unicast cell.

  A PCFICH (Physical control format indicator channel) may be provided for each subframe as a channel indicating the value of the number of OFDM symbols k through which the DPCH is transmitted. PCFICH is transmitted in the first OFDM symbol of each subframe. The notification of the allocation information of the physical resource of the PCFICH to the mobile terminal may be notified by broadcast information of the MBMS dedicated cell, or by notification in association with the frequency layer information of the MBMS dedicated cell by the broadcast information of the unicast cell. Also good. Moreover, you may decide beforehand. By determining in advance, it is possible to reduce the amount of information required for notification. Thus, by indicating the value of k for each subframe, the value of k can be changed for each subframe, and the MBMS information transmission area and the DPCH transmission area can be dynamically changed. Become. The value of k can take from 0 to the maximum number of OFDM symbols in one subframe. For example, the same 1 to 3 OFDM symbols as the PDCCH (Physical downlink control channel) of the unicast cell may be used. In this case, PCFICH is 2 bits. Also, for example, the same 1-2 OFDM symbols as the PDCCH in the MBSFN subframe of the MBMS / unicast mixed cell may be used. In this case, PCFICH is 2 bits or 1 bit. The PCFICH of a unicast cell is multiplied by a cell-specific scrambling code. However, in the present invention, the PCFICH is also multiplied by a scrambling code specific to the MBSFN area in order to enable multi-cell transmission within the MBSFN area. With the configuration as described above, the mobile terminal can perform decoding (Decode) in the same manner as the unicast cell, and the reception circuit of the mobile terminal can be simplified.

  In a unicast cell, PDSCH or PDCCH is used to transmit a paging signal, but it is necessary to include radio allocation (Resource Allocation) information in the paging signal. This is because radio allocation for communication after paging is necessary. Resources for communication after paging are transmitted using PDSCH. The PDSCH is transmitted in the remaining OFDM symbol region excluding the OFDM symbol region in which the PDCCH in the subframe is transmitted. In the paging method according to the present invention, since communication after paging is performed by a unicast cell, only paging indicators (Paging Indicator: PI) for notifying whether there is an incoming call may be used as paging information transmitted by DPCH. This is because it is not necessary to transmit radio allocation information for communication after paging. In order to be able to specify a mobile terminal only with a paging indicator, an MBSFN frame or an MBSFN subframe in which a paging indicator for a certain mobile terminal exists can be uniquely calculated from an identification number (ID) unique to the mobile terminal. It ’s fine. As another method, the base station may multiply the paging indicator by an identification number unique to the mobile terminal, and the mobile terminal may perform blind detection using the identification number unique to the mobile terminal. Furthermore, the above two methods may be combined. For example, the mobile terminals are grouped according to an identification number (ID) unique to the mobile terminal, and an MBSFN frame or an MBSFN subframe in which a paging indicator exists for the group is uniquely associated with the group. The station multiplies the paging indicator by an identification number unique to the mobile terminal.

  On the mobile terminal side, MBSFN frames and MBSFN subframes carrying the paging indicator of the group to which the mobile terminal belongs derived from the mobile terminal unique identification number are received, and blind detection is performed using the mobile terminal specific identification number. You may do it. The method for deriving the MBSFN frame or MBSFN subframe in which the paging indicator of the mobile terminal or group exists from the identification number unique to the mobile terminal may be determined in advance, or may be notified by the broadcast information of the MBMS dedicated cell from the higher layer It is good and you may notify by the alerting | reporting information of a unicast cell. MBSFN frames and MBSFN subframes in which a paging indicator is present may be periodically present. Since it is not necessary to transmit radio allocation information, it is possible to configure the DPCH with a small amount of information, and it is possible to transmit MBMS related information in the remaining area in the same subframe. Instead of mapping the paging indicator to the PCCH as shown in FIG. 30, it may be directly mapped to the PDCH in the physical layer. It is also possible to transmit DPCH using all OFDM symbols in the subframe. For example, when the number of OFDM symbols in a subframe is 7 at maximum, an arbitrary OFDM symbol from k = 0 to 7 can be used for DPCH transmission by setting the PCFICH to 3 bits and indicating the value of k. Can do. Thus, the MBMS information transmission area and the DPCH transmission area can be flexibly changed and combined in units of subframes, and the efficiency of radio resources can be improved.

  In the present invention, the case of an MBMS dedicated cell has been described. However, in the case of an MBMS / unicast mixed cell, both unicast and MBMS services are possible. Therefore, in paging in the case of an MBMS / unicast mixed cell, Requires radio assignment for post-paging communication. However, MBMS / unicast mixed cells can execute MBMS, so there exists an MBSFN subframe for MC transmission of broadcast-type MBMS data. Since there is no PDSCH in the MBSFN subframe, when the paging method in the unicast cell is applied in the MBMS / unicast mixed cell, an area for mapping the radio allocation information addressed to the individual mobile terminal cannot be secured in the MBSFN subframe. The problem arises. In this case, a method of limiting the subframe in which the paging indicator is transmitted in advance to a subframe in which the PDSCH exists, or a method of transmitting the allocation information in the PDCCH of the subframe in which the first PDSCH after the paging signal is transmitted exists. By taking this, paging in the MBMS / unicast mixed cell can be enabled.

  FIG. 18 is an explanatory diagram showing a method of mapping a paging signal to a paging dedicated channel (DPCH). FIG. 18 shows only a paging indicator (Paging Indicator: PI) as a paging signal. The paging indicator is paging information expressed by 1 bit of 1 to 0, and indicates whether there is an incoming call. The base station sets “1” to the paging indicator for the mobile terminal receiving the incoming call and maps it to the paging dedicated physical channel. The base station multiplies the paging indicator for each mobile terminal m receiving the incoming call by an identification number unique to the mobile terminal. Next, CRC (Cyclic Redundancy Check) is added to the multiplication result, and encoding (Coding) processing such as encoding (encode), rate matching, and interleaving is performed. The result of performing this series of processing is assigned to each control information element unit corresponding to the size of the physical area to be mapped, and connected to each mobile terminal that is receiving an incoming call. The connected result is subjected to spreading processing, modulation processing, and the like using a spreading code (Scrambling Code) unique to the MBSFN area. The modulation process may be specific to the MBSFN area. The results of these processes are mapped from the beginning into kOFDM symbols. At that time, the base station derives the required number of OFDM symbols k based on the result of connection for each mobile terminal that has received an incoming call, and performs processing such as encoding on the indicator corresponding to the k. , Map to PCFICH. These are performed by the same method in all cells in the MBSFN area, and multicell transmission is performed in the MBSFN area. In the present embodiment, the number of OFDM symbols (k) for transmitting DPCH is set to 1. DPCH is mapped to the first OFDM symbol of the subframe together with PCFICH and reference symbols.

In a mobile terminal receiving a signal transmitted by multicell transmission, the number of OFDM symbols used for paging is determined based on the received PCFICH decoding result, and demodulation processing, despreading processing, etc. are performed. After these processes, the image is divided into certain areas, sequentially subjected to deinterleaving, decoding (decoding), error detection, correction processing, and the like, and blind detection is performed using a terminal-specific identification number. When the identification number of the mobile terminal is detected by blind detection, it can be determined that paging has occurred. For PCFICH, reference symbols, etc., mapping to physical resources is performed by a predetermined method, for example. You may use the method similar to a unicast cell. By using the same method as the unicast cell, it is possible to simplify the configuration of the base station and the configuration of the receiving circuit of the mobile terminal. When the mobile terminal has the same amount of information as in the case where the paging signal is only the paging indicator, the size of the control information element unit for allocating the coding result may be one. By making the encoding processing etc. the same in all mobile terminals that receive paging, the size of the control information element after encoding can be made one. As a result, when a mobile terminal performs blind detection of an identification number unique to the mobile terminal, it suffices to perform processing such as decoding for each control information element unit of one size, thereby reducing the time for blind detection. And the detection speed can be increased. Further, instead of multiplying the identification number unique to the mobile terminal, a code unique to each mobile terminal may be used as a paging indicator, and an equivalent effect can be obtained.

  FIG. 19 is an explanatory diagram showing a method of mapping a paging signal to a paging dedicated channel (DPCH). FIG. 19 shows only the paging indicator (PI) as the paging signal. The paging indicator is paging information represented by 1 bit of 1/0, and indicates whether there is an incoming call. The base station sets “1” in the paging indicator for the mobile terminal receiving the incoming call and maps it to the paging dedicated physical channel. The base station adds CRC to the paging signal of each mobile terminal, and performs processing such as encoding (encode), rate matching, and interleaving. The result of performing these processes is multiplied by an identification code (number) unique to the mobile terminal. The orthogonality is obtained between the mobile terminals by using an identification code unique to the mobile terminal as a spreading code having orthogonality. The base station multiplexes the result of multiplying the spreading code for each mobile terminal that is receiving an incoming call. The multiplexed result is subjected to spreading processing, modulation processing, etc. using a spreading code (Scrambling Code) unique to the MBSFN area. The modulation process may be specific to the MBSFN area. The results of these processes are mapped from the beginning into kOFDM symbols. When the number of mobile terminals is large, it is divided into a plurality of groups, multiplied by a mobile terminal identification code so as to obtain orthogonality among the mobile terminals in the group, and multiplexed for the mobile terminal, and an MBSFN area specific spreading code Performs diffusion processing, modulation processing, and the like. These processes may be performed for each group and then mapped to different OFDM symbols. At that time, the base station derives the required number of OFDM symbols k based on the result of multiplexing each mobile terminal receiving the incoming call, performs an encoding process or the like on the indicator corresponding to the k, and PCFICH To map. These are performed by the same method in all cells in the MBSFN area, and multicell transmission is performed in the MBSFN area. In the present embodiment, the number of OFDM symbols (k) for transmitting DPCH is set to 1. DPCH is mapped to the first OFDM symbol of the subframe along with PCFICH, reference symbols, and the like. In a mobile terminal receiving a signal transmitted by multi-cell transmission, the number of OFDM symbols used for paging is determined from the received physical resource based on the PCFICH decoding result, and demodulation processing, descrambling processing, and the like are performed. After these processes, the image is divided into certain areas, a correlation calculation is performed using a terminal-specific identification number, and blind detection is performed. When the identification code of the own mobile terminal is detected by blind detection, it can be determined that paging has occurred, and a paging signal is received by performing deinterleaving, decoding, error detection, correction processing, and the like.

  Although several methods for mapping the paging signal to the paging dedicated channel (DPCH) have been disclosed, the mapping to the paging dedicated channel region may be any predetermined region or localized (continuous on the frequency axis). May be mapped to a distributed physical area (distributed on the frequency axis).

  This embodiment may be applied not only to the case where the PMCH configuration for each MBSFN area is code division multiplexed, but also to the case where time division multiplexing and both time division multiplexing and code division multiplexing are applied.

  In the mobile terminal, it is necessary to know at which timing the paging signal for the mobile terminal is mapped on the DPCH of the MBSFN frame or MBSFN subframe, but as a method therefor, it may be derived by a predetermined calculation method. Alternatively, it may be notified from the upper layer as broadcast information from the serving cell of the unicast service or the MBMS dedicated cell. The timing may be periodic. When the paging signal is transmitted at a certain period, the mobile terminal can perform an intermittent reception operation during the time when the paging signal is not transmitted if the MBMS service is not received. Therefore, the power consumption of the mobile terminal can be reduced.

  Since the mobile terminal can blindly detect whether the information is addressed to the mobile terminal by using an identification code or a spreading code unique to the mobile terminal, the physical area for mapping the paging signal for each mobile terminal is fixed in advance. There is no need to have a physical area for paging signals for all mobile terminals, and there is only an area for the number of mobile terminals that are expected to actually receive incoming calls. It can be used effectively. In the above example, the base station multiplies the paging signal by the identification number unique to the mobile terminal. However, it is also possible to use a method of multiplying CRC instead of a paging signal by an identification number unique to the mobile terminal. The method of multiplying the CRC by the identification number unique to the mobile terminal is effective when the information amount of the paging signal of each mobile terminal is different.

  In the case of the method of placing a paging signal on the PMCH for each MBSFN area disclosed in the first embodiment, the frequency of the PMCH on which the paging signal can be carried decreases with time. Therefore, there arises a problem that paging signals for many or all mobile terminals must be mapped to one PMCH carrying the paging signal. In order to solve this problem, the first embodiment disclosed a method such as paging grouping. In the second embodiment, the above problem can be solved by providing a paging-dedicated physical channel for multi-cell transmission in the MBSFN area and placing a paging signal on the physical channel. In addition, since the mobile communication system can transmit a paging signal of a mobile terminal that is receiving or is about to receive an MBMS service from the MBMS dedicated cell, the mobile terminal can receive the paging signal in the MBMS dedicated cell. Become.

  In the example of the present embodiment, in a certain cell, a part of the MBSFN subframe corresponding to the MBSFN area to which the cell belongs is set as a physical channel dedicated to paging (referred to as DPCH), and the DPCH is provided for each subframe. However, it may be transmitted periodically instead of every subframe. For example, a part of the MBSFN subframe corresponding to each MBSFN area may be transmitted as a paging-dedicated physical channel (referred to as DPCH) once every two subframes or once per radio frame. Depending on the number of mobile terminals considered in the system, the repetition period of transmission as DPCH of each MBSFN area may be determined based on the number of mobile terminals that can simultaneously transmit paging and the frequency of paging. As a result, a subframe in which no DPCH is transmitted can be used as an MBMS service data area, and the speed of the MBMS service can be increased.

Embodiment 3 FIG.
In the second embodiment, a method for providing a paging-dedicated physical channel for multi-cell transmission in an MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area and placing a paging signal on the physical channel has been disclosed. In the following, Embodiment 3 discloses a method of providing a physical channel to be transmitted in multi-cell (multi cell) within the MBSFN synchronization area and placing a paging signal on the physical channel.

  FIG. 20 is an explanatory diagram showing a configuration of a physical channel (referred to as main PMCH) transmitted in multicell within the MBSFN synchronization area. This shows a case where time division multiplexing and code division multiplexing are mixed as PMCH provided for each MBSFN area. Cell # n1 is a cell in MBSFN area 1, cell # n2 is a cell in MBSFN area 2, and cell # n3 is a cell in MBSFN area 3. The cells # n1, # n2, and # n3 are also cells in the MBSFN area 4. The PMCHs in MBSFN areas 1, 2, and 3 are code division multiplexed, and the PMCHs in MBSFN areas 1, 2, and 3 and the PMCH in MBSFN area 4 are time division multiplexed. The main PMCH is time-division multiplexed with the PMCH for each MBSFN area. Since cell # n1 belongs to MBSFN area 1 and MBSFN area 4, PMCH1 and PMCH4 are time-division multiplexed, and the main PMCH is time-division multiplexed. The same applies to cell # 2 and cell # 3. Since the main PMCH is transmitted by multicell in the MBSFN synchronization area, the main PMCH is transmitted on an MBSFN subframe in which SFN combining is performed. A set of MBSFN frames to which MBSFN subframes are allocated is referred to as an MBSFN frame cluster. In the MBMS dedicated cell, all subframes in the MBSFN frame may be MBSFN subframes used for multicell transmission. A period in which the main PMCH is repeated is referred to as a “main PMCH repetition period”. MCH, which is a transport channel for MBMS, is mapped to the main PMCH. MCCH, which is a logical channel for transmitting MBMS control information, and MTCH, which is a logical channel for transmitting MBMS data, or both are mapped to MCH. MCCH and MTCH may be divided in time and mapped onto the main PMCH, or may be divided in time and mapped to a physical region that is transmitted in multicell.

  For example, MBSFN subframes that are physical areas to which MTCH and MCCH are mapped as a result may be different. The MCCH may be mapped to each MBSFN frame cluster in which the main PMCH is transmitted, or only the MTCH may be mapped. When only MTCH exists, the MCCH repetition period is different from the main PMCH repetition period. In some cases, a plurality of MCCHs are mapped on the MBSFN frame cluster in which the main PMCH is transmitted. The MCCH repetition period is referred to as “MCCH repetition period”. In FIG. 20, MCCH1 (MCCH2,3,4) is MBMS control information for MBSFN area 1 (MBSFN area 2,3,4), and MTCH1 (MTCH2,3,4) is MBSFN area 1 (MBSFN area 2,3, 4) Transmit MBMS data for use. Each MCCH may be mapped on each PMCH, or only MTCH. When only MTCH exists, MCCH of each MBSFN area may be mapped to main PMCH. Further, it may be included as an information element of MCCH mapped to the main PMCH. Since the main PMCH is transmitted by multicell in the MBSFN synchronization area, it is impossible to multiply the main PMCH by a spreading code (Scrambling Code) unique to the MBSFN area as in the PMCH of each MBSFN area. This is because the main PMCH is transmitted from the cells of different MBSFN areas at the same timing, and therefore when the main PMCH is multiplied by a spreading code specific to the MBSFN area, the mobile terminal receiver transmits the main PMCH transmitted from each MBSFN area. This is because the phase of the main PMCH becomes random and SFN synthesis cannot be performed. Therefore, as shown above, the main PMCH and the PMCH of each MBSFN area can be time-division multiplexed to multiply each MBSFN area-specific spreading code in units of subframes, and only the main PMCH. It is possible not to multiply the spreading code unique to each MBSFN area. As a result, the main PMCH can be transmitted in a multi-cell manner in the MBSFN synchronization area, and the mobile terminal can receive the main PMCH regardless of which MBMS service is received in the MBSFN synchronization area. In addition, an SFN gain can be obtained. Although it has been described that the main PMCH is not multiplied by a unique spreading code, it may be multiplied if it is a spreading code unique to the MBSFN synchronization area. In this case, interference from other cells in the MBSFN synchronization area can be suppressed, and the reception error of the MBMS service in the mobile terminal can be reduced.

  FIG. 21 is an explanatory diagram showing a configuration of a radio frame in which the main PMCH is transmitted. In FIG. 21, the subframes in which the main PMCH is transmitted are subframes # k1 to # k2 excluding # 0 and # 5 (k1 to k2 ≠ 1, 5). In an MBMS dedicated cell, it is considered that a synchronization channel (SCH) is transmitted in subframes # 0 and # 5 in one radio frame. In addition, it is considered that a broadcast channel (BCH) is transmitted in the # 0 subframe. It is considered that the synchronization channel (SCH) includes a cell-specific sequence or MBSFN area-specific sequence, and the broadcast channel (BCH) is multiplied by a cell-specific spreading code or MBSFN area-specific spreading code. Therefore, the subframe in which the main PMCH is transmitted is a subframe excluding # 0 and # 5, so that multicell transmission can be performed in the MBSFN synchronization area. Even if the MBMS service is received or about to be received, the main PMCH can be received, and further, an SFN gain can be obtained. In the figure, the subframes in which the main PMCH is transmitted are continuous, but may not be continuous. By making it continuous in the subframes excluding # 0 and # 5, it becomes possible for the mobile terminal to perform intermittent reception during other subframe periods that do not require reception, thereby reducing the reception power. The main PMCH may not be provided every radio frame, and may be provided periodically, for example, every 2 radio frames or every 10 radio frames. The period of the main PMCH is represented by a “Main PMCH repetition period”. As a result, the PMCH of the subframe that does not transmit the main PMCH can be used as the MBMS service data area, and the speed of the MBMS service can be increased. The start timing (SFN, starting point) of the radio frame and subframe in which the main PMCH exists, the subframe number, and the main PMCH repetition period may be notified by broadcast information of the unicast side serving cell, or broadcast information of the MBMS dedicated cell You may be notified at. It may be determined in advance. Since the main PMCH is transmitted in multicell, the subframe in which the main PMCH exists may be an MBSFN subframe and the radio frame may be an MBSFN frame.

  FIG. 22 is an explanatory diagram showing a configuration of a radio frame in which the main PMCH is transmitted in the same subframe as the synchronization channel SCH. FIG. 22 shows a configuration in which the subframe in which the main PMCH is transmitted is # 5 and the main MCH is mapped outside the region to which the synchronization channel SCH is mapped. FIG. 21 shows a configuration in which subframes are mapped to subframes excluding # 0 and # 5. This is because all the OFDM symbols in the subframe can be multi-cell transmitted in the MBSFN synchronization area. Therefore, the transmitter of the base station and the receiver of the mobile terminal can be simplified. In FIG. 22, the main PMCH is further configured as all or part of the area excluding the physical area to which the synchronization channel SCH of the subframe # 5 is mapped. It has been described that the synchronization channel SCH is transmitted in the subframes # 0 and # 5 in one radio frame in the MBMS dedicated cell. Here, since the broadcast channel BCH is not transmitted in the subframe # 5, it is not necessary to multiply the cell-specific spreading code or the MBSFN area-specific spreading code. Therefore, it is possible to use all or part of the area of the # 5 subframe excluding the physical area to which the synchronization channel SCH is mapped for the main PMCH. For example, when the SCH is mapped to the sixth and seventh OFDM symbols of the # 5 subframe, the first to fifth and eighth to last OFDM symbols are used as the main PMCH region. In this way, the main PMCH can be transmitted by multicell in the MBSFN synchronization area, and the mobile terminal receives the main PMCH regardless of which MBMS service in the MBSFN synchronization area is being received or is about to be received. In addition, an SFN gain can be obtained. By allowing the # 5 subframe to be used also for the main PMCH, the flexibility of the system is increased and the efficiency of radio resources can be improved.

  FIG. 23 is an explanatory diagram showing the configuration of the main PMCH provided with a paging signal area. FIG. 23A is a diagram showing a configuration including MBMS related information and a paging signal on the main PMCH. Each of the MBMS related information and the paging signal may exist as an information element in the MTCH and MCCH, or a physical area (resource) to which each is mapped may be time-division multiplexed. In the case of the mapping method in the case of being put as an information element, the method disclosed in FIG. 27 can be applied as an example. The physical channel PMCH in FIG. 27 may be the main PMCH. Among the MBMS related information, a paging signal is put on the logical channel MCCH as an information element together with MBMS control information. The MCCH is mapped to the transport channel MCH together with the MTCH, and the MCH is mapped to the main PMCH that is a physical channel. This makes it possible to receive a paging signal when a mobile terminal that is receiving or intending to receive an MBMS service receives the MCCH. As another example, the method disclosed in FIG. 28 can be applied. The PMCH that is the physical channel in FIG. 28 may be the main PMCH. The logical channel PCCH carrying the paging signal is multiplexed with the logical channels MTCH and MCCH of the MBMS related information and placed on the transport channel MCH. The base station may provide an MBSFN subframe for MTCH only, an MBSFN subframe for mapping MCCH and PCCH, and control to provide an MBSFN subframe for MCCH only and an MBSFN subframe for PCCH only. You may do it. In this way, transmission can be performed after being divided in time. Also, MBSFN subframes carrying MCCH and PCCH may be temporally adjacent. This makes it possible to receive a paging signal when a mobile terminal that is receiving or intending to receive an MBMS service receives the MCCH.

  As yet another example, the method disclosed in FIG. 29 can be applied. The physical channel PMCH in FIG. 29 may be the main PMCH. The PCCH carrying the paging signal is mapped to the transport channel PCH, multiplexed with the MCH, and mapped to the main PMCH. In this way, the base station can transmit the PCH and MCH by dividing them in time, and further can perform encoding separately. Therefore, the mobile terminal can perform decoding separately at the time of reception. In the above example, the difference from Embodiment 1 is that MTCH, MCCH, and PCCH mapped to the main PMCH are transmitted in multicells in the MBSFN synchronization area, not in the MBSFN area. Therefore, the PMCH transmitted in multicell in the MBSFN area and the main PMCH transmitted in multicell in the MBSFN synchronization area may be clearly divided. FIG. 31 is an explanatory diagram showing a mapping method when the main PMCH is provided as a physical channel common to the MBSFN synchronization area. FIG. 31 discloses the mapping when the PMCH and the main PMCH are provided. This example shows the case where MCH and PCH in FIG. 29 are used. MTCH and MCCH, which are MBMS related information to be transmitted into the MBSFN area, are mapped to the transport channel MCH and mapped to the physical channel PMCH. The PMCH is transmitted in an MBSFN subframe corresponding to the MBSFN area. MTCH and MCCH, which are MBMS related information to be transmitted into the MBSFN synchronization area, are mapped to the transport channel MCH and mapped to the main PMCH, which is a physical channel. The PCCH carrying the paging signal transmitted into the MBSFN synchronization area is mapped to the transport channel PCH and mapped to the main PMCH which is a physical channel. The main PMCH is transmitted in an MBSFN subframe transmitted in multi-cells in the MBSFN synchronization area.

  Also, for the logical channel and / or transport channel, the MBSFN area use and the MBSFN synchronization area use may be provided separately. For example, the case where only the MBMS control information is transmitted in the MBSFN synchronization area is indicated by a broken line in FIG. The logical channel MCCH transmitted in the MBSFN synchronization area may be the main MCCH, for example, and the transport channel MCH may be the main MCH, for example. The main MCH is mapped to the main PMCH, which is a physical channel. By making such an individual, scheduling in the base station, HARQ (Hybrid Automatic Repeat reQuest) processing, encoding processing, AMC (Adaptive Modulation Coding) processing, etc. can be performed individually in the MBSFN synchronization area and the MBSFN area. In addition, it becomes possible to flexibly cope with fluctuations in the radio wave environment between the base station and the mobile terminal, and it is possible to improve the efficiency of radio resources. The MCCH transmitted in multicell within the MBSFN synchronization area includes service information, frame configuration information, and the like of each MBSFN area included in the MBSFN synchronization area. Also, MBMS service control information for each MBSFN area may be included. In this case, since it is not necessary to transmit the MCCH on the PMCH for each MBSFN area, the MBMS data area can be increased, and the speed of MBMS transmission can be increased. MCCHs transmitted in multi-cells in the MBSFN synchronization area are periodically transmitted in multi-cells in each MBSFN synchronization area in the main PMCH repetition period.

  On the other hand, a mobile terminal that is receiving or intending to receive an MBMS service transmitted from a cell in a certain MBSFN area periodically receives the MCCH on the main PMCH and receives the contents of the MBMS service, the frame configuration, and the like. By doing so, the MBMS service can be received. Therefore, after receiving and decoding the MCCH on the main PMCH, the mobile terminal can perform intermittent reception operation until the next main PMCH without receiving a PMCH corresponding to another MBSFN area when there is no desired service. It becomes possible. Therefore, the power consumption of the mobile terminal can be reduced. Further, by including a paging signal in the MCCH, it is possible to receive a paging signal when a mobile terminal receiving or attempting to receive an MBMS service receives the MCCH. This eliminates the need for the mobile terminal to separately receive paging at a timing other than receiving the MCCH, and thus enables paging to be received without interrupting reception of the MBMS service. Further, intermittent reception can be performed during a period when the MCCH is not received and during a period when the MBMS service is not being received, so that power consumption of the mobile terminal can be reduced. When the method disclosed in FIG. 28 is applied, MCCH and PCCH may be configured in the same MBSFN subframe, or an MBSFN subframe on which MCCH is carried and an MBSFN subframe on which a paging signal is carried are temporally adjacent. You may do it. When the method disclosed in FIG. 29 is applied, the MBSFN subframe carrying the MCCH and the MBSFN subframe carrying the paging signal may be temporally adjacent. With this configuration, it is possible to continuously receive a paging signal when a mobile terminal that is receiving or intending to receive an MBMS service receives an MCCH. This eliminates the need for the mobile terminal to receive a separate paging signal at a timing other than receiving a subframe carrying MCCH and PCCH, and thus enables the mobile terminal to receive the paging signal without interrupting reception of the MBMS service. Further, intermittent reception can be performed during a period when the MCCH is not received and during a period when the MBMS service is not being received, so that power consumption of the mobile terminal can be reduced.

  FIG. 23B discloses a configuration in which an “MBMS related information change presence / absence indicator” indicating whether MBMS control information has been changed and a “paging signal presence indicator” indicating whether a paging signal has been transmitted are disclosed. The physical area to which these indicators are mapped may be provided in the MBSFN subframe in which the main PMCH is transmitted, or in the physical area temporally adjacent to the MBSFN subframe in which the main PMCH is transmitted. Also good. By doing so, the mobile terminal can receive and decode the MCCH and the paging signal on the main PMCH immediately after receiving the indicator. For example, 1-bit information is used as an indicator. Each indicator is encoded or mapped to a predetermined physical region, such as multiplied by a spreading code specific to the MBSFN synchronization area. For example, when an incoming call occurs in the mobile terminal, the paging signal presence / absence indicator is set to “1”, and when there is no incoming call, the paging signal presence / absence indicator is set to “0”. Also, for example, when MBMS control information on the MCCH is changed due to a change in the content of the MBMS service transmitted in the MBSFN synchronization area, the MBMS related information change presence / absence indicator is set to “1”. . A period (MBMS modification period) in which MBMS related information can be changed is determined, and a change presence / absence indicator “1” is repeatedly transmitted within the period. The MBMS modification period, the start timing (SFN, starting point), etc., in which MBMS-related information can be changed may be determined in advance, from the serving cell in the unicast service, or from the MBMS dedicated cell with the broadcast information You may be notified. If the MBMS related information is not changed after the period (MBMS modification period) has passed, the MBMS related information change presence / absence indicator is set to “0”.

  The mobile terminal receives an indicator in an MBSFN subframe in which the main PMCH is transmitted in a multi-cell manner or an adjacent MBSFN subframe, performs despreading, etc., and determines whether the indicator is 1 or 0, so that the MBMS existing in the MCCH It is possible to determine whether the related information has changed or whether paging exists. By providing the indicator in this way, when there is no change in the MBMS control information or when there is no paging, the mobile terminal does not need to receive and decode all the information on the main PMCH. For this reason, it is possible to reduce the reception power of the mobile terminal. The physical area to which the MBMS-related information change presence / absence indicator indicating whether the MBMS control information has been changed may be the first MBSFN subframe of one or more MBSFN subframes to which the MBMS control information is mapped. Further, it may be the first OFDM symbol of the first MBSFN subframe. Accordingly, the mobile terminal can determine whether the MBMS control information has changed by receiving the first OFDM symbol. Further, a physical area to which a paging signal presence / absence indicator indicating whether or not a paging signal is present may be used as the first MBSFN subframe of one or a plurality of MBSFN subframes to which the paging signal is mapped. Further, it may be the first OFDM symbol of the first MBSFN subframe. As a result, the mobile terminal can determine whether a paging signal exists by receiving the first OFDM symbol.

  By mapping each indicator to the physical area as described above, when there is no MBMS control signal change, when there is no paging information, it is not necessary to receive and decode each subsequent OFDM symbol, and the received power of the further mobile terminal Can be reduced. In addition, since it can be determined early with the first MBSFN subframe or the first OFDM symbol, the MBMS control information can be received immediately or the paging signal can be received immediately. Control delay can be reduced. As an indicator, the MBMS related information change presence / absence indicator and the paging signal presence / absence indicator may be mapped to different physical areas, or may be mapped to different physical areas. When mapping to the same physical area, an OR operation of each indicator may be taken. As a result, since the mobile terminal needs only one indicator to receive, the effect of simplifying the receiving circuit configuration can be obtained. In the case of mapping to different physical areas, this allows the mobile terminal to receive only the necessary indicators and eliminates the need to receive other indicators. Therefore, it is possible to further reduce the reception power of the mobile terminal and further reduce the reception delay of necessary information. For example, in a mobile terminal that has received an MBMS service but is set not to receive paging, it is only necessary to receive an MBMS-related information change presence / absence indicator, eliminating the need to receive a paging signal presence / absence indicator. it can. The repetition period of each indicator may be the same or different. The repetition period of each indicator may be the same as or different from the repetition period of the main PMCH. For example, an MBMS related information change presence / absence indicator may be provided in the main PMCH once in several times. The repetition period of the indicator is “paging signal presence / absence indicator repetition period” and “MBMS-related change presence / absence indicator repetition period”, respectively. The start timing (SFN, starting point) of the MBSFN subframe in which the indicator exists, the subframe number, the repetition period of each indicator, etc. may be notified by the broadcast information of the serving cell of the unicast service, or the broadcast of the MBMS dedicated cell It may be notified by information or may be determined in advance.

  Furthermore, a channel dedicated to the change presence / absence indicator of MBMS related information may be configured on the main PMCH, for example, MICH (MBMS Indicating CHannel). A paging signal presence / absence indicator is formed in the MICH, and the MICH repetition period is set to “MICH repetition period”. The repetition period of the paging signal presence / absence indicator may be the same as or different from the MICH repetition period. The notification of the indicator can be performed by the same method as described above. Thereby, the time when each indicator is transmitted is not limited to the time when MCCH is transmitted, and the system can be designed flexibly. When configured as described above, the MBMS related information change presence / absence indicator indicates whether the MBMS control information on the main PMCH has been changed. It is unclear just by detecting the indicator. Whether the MBMS service transmitted in the desired MBSFN area has been changed must receive and decode the MBMS control information on the main PMCH. As the MBMS control information on the main PMCH, an indicator may be provided that indicates in which MBSFN area the MBMS service transmitted has been changed. The physical area for the indicator may be provided immediately before the MBSFN subframe carrying the MBMS control information on the main PMCH. In this way, it is possible to detect whether the MBMS service transmitted in a desired MBSFN area has been changed without having to receive and decode all MBMS control information on the main PMCH. Therefore, it is possible to reduce the control delay at the mobile terminal.

  When the paging signal is put on the main PMCH, there is a problem that it takes too much time to detect the paging signal addressed to the own mobile terminal when the number of mobile terminals that have received an incoming call becomes enormous. Further, there arises a problem that an area for mapping paging signals of all mobile terminals that have received incoming calls cannot be secured in a predetermined physical area carrying a paging signal. In order to solve these problems, a paging grouping method is disclosed. FIG. 23C shows a configuration example of the paging signal presence / absence indicator. All mobile terminals are divided into K groups, and a paging signal presence / absence indicator is provided for each group. The physical area for the paging signal presence / absence indicator is divided into K pieces, and the paging signal presence / absence indicator of each group is mapped to each of the divided physical areas. Here, K can take from 1 to the value of the total number of mobile terminals. When an incoming call is received at a certain mobile terminal, the paging signal presence / absence indicator of the group to which the mobile terminal belongs is set to “1”. When all mobile terminals belonging to a certain group do not receive an incoming call, the paging signal presence / absence indicator of that group is set to “0”. The paging signal presence / absence indicator may be subjected to repetition or the like in which “1” (or “0”) is repeatedly mapped to the physical area in order to satisfy a desired reception error rate at the mobile terminal. The physical area to which the paging signal is mapped is also divided into K pieces so as to correspond to the K groups. The paging signal may be an identifier (identification number, identification code) for each mobile terminal. One physical area divided into K is a physical area in which paging signal data required by one mobile terminal is accommodated by adding the number of mobile terminals in the group. The number of mobile terminals in a group may be the same in all groups, or may be different for each group. For example, the number of mobile terminals in the group may be an average value of the number of mobile terminals that simultaneously receive incoming calls. Alternatively, the number of mobile terminals that can be assigned to one OFDM symbol may be used, and each OFDM symbol may be associated with each group.

  When an incoming call occurs at a certain mobile terminal, the paging signal presence / absence indicator of the group to which the mobile terminal belongs is set to “1” and mapped to the paging signal presence / absence indicator physical area corresponding to the group. At the same time, the paging signal for the mobile terminal that has received the incoming call is mapped to the paging-related physical area corresponding to the group to which the mobile terminal belongs. The mapping of the paging signal to the physical channel region is multiplied for each mobile terminal by an identification code unique to the mobile terminal. When the paging signal is an identifier for each mobile terminal, the control for multiplying the mobile terminal specific identification code can be omitted. The mobile terminal receives the paging signal presence / absence indicator of the group to which the mobile terminal belongs to determine whether an incoming call has been made to the group to which the mobile terminal belongs. When it is determined that the incoming call is received, the physical area to which the paging signal associated with the group to which the mobile terminal belongs is received and decoded. After decoding, blind detection is performed by performing correlation calculation with an identification code unique to the mobile terminal, and it is possible to determine that there is an incoming call to the mobile terminal by specifying a paging signal for the mobile terminal. . If no paging signal for the mobile terminal is detected, it is determined that there is no incoming call to the mobile terminal. By grouping the mobile terminals into K groups, the mobile terminal does not need to receive the entire paging signal area, and only receives the necessary area, that is, only the physical area to which the group to which the mobile terminal belongs corresponds. Therefore, the reception power of the mobile terminal can be reduced. Furthermore, by using a paging signal presence / absence indicator corresponding to each group, a paging signal presence / absence indicator can be provided with few physical resources even when there are a large number of mobile terminals. Furthermore, the mobile terminal only needs to receive the paging signal area as needed, and it is possible to reduce the reception power of the mobile terminal, and when it is not necessary to receive the paging signal, the mobile terminal immediately moves to the next operation. Therefore, the control delay can be reduced.

  In the above embodiment, one physical area divided into K pieces for mapping the paging signal is obtained by adding the physical area in which the paging signal data required by one mobile terminal is accommodated by the number of mobile terminals in the group. It was supposed to be a physical area. However, when the number of mobile terminals increases, the required physical area increases, and the overhead for transmitting the MBMS service increases, so the transmission speed of MBMS service data decreases. In order to prevent this, the paging signal for the mobile terminal is multiplied by an identification code unique to the mobile terminal for each mobile terminal. As a result, the mobile terminal can blindly detect whether the information is addressed to its own mobile terminal using an identification code unique to the mobile terminal, so that the physical area for mapping the paging signal for each mobile terminal is fixed in advance. There is no need to keep it. Therefore, the physical area for all the mobile terminals is not required, and there may be an area for the number of mobile terminals that are expected to actually receive incoming calls. As an example, there is a method in which the number of mobile terminals in the group is an average value of the number of mobile terminals that receive incoming calls simultaneously. This method makes it possible to effectively use limited physical resources. In addition, with the above method, when the number of mobile terminals receiving more than expected is increased, a paging signal to a new incoming mobile terminal is transmitted on the next main PMCH. It becomes possible to respond flexibly by scheduling.

  When the total number of mobile terminals is small, only the paging signal presence / absence indicator may be transmitted with the value of K as the total number of mobile terminals. In this case, it is not necessary to secure a paging signal area, and it is sufficient to secure physical areas for paging signal presence / absence indicators for the number of all mobile terminals. For this reason, it is possible to improve the efficiency of radio resources. In this case, a physical area for a paging signal presence / absence indicator corresponding to each mobile terminal exists. For this reason, in the mobile terminal, it is possible to determine the presence / absence of an incoming call without receiving the paging signal area only by receiving and decoding the physical area for the paging signal presence / absence indicator corresponding to the mobile terminal. The control delay in the paging operation can be reduced.

  The method disclosed in the first embodiment can be applied to the method for mapping the paging signal to the paging-related physical area of the main PMCH. For example, it is the method of FIG. 13 or FIG. However, in the modulation process, the spreading process, etc., the step of multiplying the MBSFN area specific spreading code is not applicable, and it is necessary not to multiply the MBSFN area specific spreading code or to multiply the MBSFN synchronization area specific spreading code. is there.

  In the above example, the method disclosed in the first embodiment is applied as a method for mapping the configuration of the main PMCH and the paging signal to the main PMCH. Similarly, for example, when the frequency of transmission of the main PMCH is high in time, the method disclosed in the second embodiment can be applied as a method of mapping the configuration of the main PMCH and the paging signal to the main PMCH. .

  By providing a physical channel for multi-cell transmission in the MBSFN synchronization area disclosed in the third embodiment and placing a paging signal on the physical channel, an MBMS service can be used from an MBMS dedicated cell as a mobile communication system. The paging signal of all mobile terminals that are receiving or are about to receive can be transmitted, and the mobile terminal can receive the paging signal from the MBMS dedicated cell.

Embodiment 4 FIG.
In the above embodiments, a method has been disclosed in which a paging signal is provided so as to be transmitted in a multi-cell manner from all cells in the MBSFN area or the MBSFN synchronization area. It is conceivable that the MBSFN area and the MBSFN synchronization area are geographically vast. In such a case, transmitting a paging signal for the mobile terminal from a cell that does not contribute to SFN combining in the mobile terminal wastes radio resources and causes a reduction in system capacity. Therefore, it becomes necessary to limit the cell that transmits the paging signal to a cell in which the mobile terminal exists and a neighboring cell. When the cell that transmits the paging signal is limited to the cell in which the mobile terminal exists and the neighboring cell, the cell that transmits the paging signal to a certain mobile terminal and the cell that does not transmit are generated in the same MBSFN area or the same MBSFN synchronization area. Thus, different signals are transmitted between cells, and multi-cell transmission is not performed. Since the mobile terminal cannot selectively limit the cells to be received, a signal that is not multi-cell transmission is also received, causing a reception error. The reception quality of a desired paging signal deteriorates due to a different signal transmitted from a cell that does not transmit a paging signal. In particular, a reception error increases for a mobile terminal that exists near the boundary between a cell that transmits a paging signal and a cell that does not transmit a paging signal, and a paging signal cannot be received. Therefore, this embodiment discloses a configuration in which a cell that transmits a paging signal and a cell that does not transmit a paging signal are provided.

  In order to reduce paging signal reception errors at the mobile terminal, the method of mapping the paging signal is changed between the cell that transmits the paging signal and the cell that does not transmit the paging signal. FIG. 24 is an explanatory diagram showing a method of transmitting a paging signal to some cells in the MBSFN area or the MBSFN synchronization area. As shown in FIG. 24, in the cell that transmits the paging signal, as described with reference to FIG. 13 or FIG. 18, the signal is multiplied by the identification number unique to the mobile terminal, and a series of processing is performed. A result is assigned to each control information element unit, and processing is performed until each mobile terminal that receives an incoming call is connected. On the other hand, such processing is not performed in a cell that does not transmit a paging signal. The physical area where the paging signal is carried includes the PMCH, DPCH, and main PMCH shown in the above embodiment. In the MBSFN area or the MBSFN synchronization area, if there is a cell that transmits a paging signal and a cell that does not transmit to a mobile terminal that has received an incoming call, the cell in the cell that transmits the paging signal Connect 2401 to terminal a. The paging signal to the mobile terminal is multiplied by an identification number unique to the mobile terminal, CRC is added, and processing such as encoding and rate matching is performed. Since the switch 2401 is connected to the terminal a, the information after the above processing for each mobile terminal is assigned to a certain control information element unit.

  On the other hand, in a cell that does not transmit a paging signal, the base station connects the switch 2401 in the figure to the terminal b. Without using a paging signal to the mobile terminal, a padding code is provided for each cell, and the padding code is assigned to each control information element unit. Here, the area of the control information element unit allocated to a certain mobile terminal is the same in a cell that transmits a paging signal and a cell that does not transmit. As a result, the base station can easily switch the information to be allocated between the cell that transmits the paging signal and the cell that does not transmit the paging signal by the switch. Furthermore, by making the size of the control information element unit area allocated to a certain mobile terminal the same for all mobile terminals, it becomes possible to determine the padding code length for each cell in advance. . Thus, padding code embedding control can be easily configured. On the other hand, a mobile terminal receiving or trying to receive an MBMS service transmitted from a cell in a certain MBSFN area or MBSFN synchronization area receives or demodulates a PMCH, DPCH or main PMCH to which a paging signal is mapped. Processing, despreading processing, and the like are performed to divide the area into control information element units. The divided control information element unit area is decoded and the like, and the correlation calculation is performed using the identification number unique to the own terminal, thereby blindly detecting the paging signal for the own mobile terminal. If the correlation calculation result is greater than a certain threshold, it is determined that there is paging for the mobile terminal, and a paging incoming operation is started by a paging signal. If it is less than a certain threshold value, it is determined that there is no paging for the terminal itself, and the process shifts to reception of MBMS related information, or shifts to the intermittent reception operation if it is not necessary to receive MBMS related information.

  If the transmission signal from the cell that does not transmit the paging signal is different from the transmission signal from the cell that transmits the paging signal, the multi-cell transmission is not performed, and not only the SFN gain cannot be obtained by the multi-cell transmission, but also the paging signal is changed. A transmission signal from a cell that does not transmit becomes noise, and errors increase in the correlation calculation result at the mobile terminal. As disclosed in the present embodiment, in a cell that does not transmit a paging signal, a padding (embedding, setting) code is determined in advance, and the padding code is embedded in an area where the paging signal is mapped, It is possible to reduce errors in correlation calculation at the mobile terminal. FIG. 25 is an explanatory diagram illustrating an example of a padding code for each cell provided in a cell that does not transmit a paging signal. For example, a cell that does not transmit a paging signal has a padding code of “all 0” (all 0). In this case, the same code, that is, “all 0” is set in all cells not transmitting the paging signal. In this way, since the mobile terminal has an interference canceling function such as an interference canceller in the mobile terminal, the mobile terminal can cancel the “0” component transmitted from the cell that does not transmit the paging signal. Only the paging signal transmitted from the cell transmitting the signal can be SFN-combined, and the reception error of the paging signal in the correlation calculation at the mobile terminal can be reduced. The padding code for cells that do not transmit paging may be “all 1”. In this case, the same code, that is, all 1 is set in all cells that do not transmit paging. Also in this case, since the mobile terminal has an interference canceling function such as an interference canceller, the “1” component can be canceled, and the reception error of the paging signal at the mobile terminal can be reduced. It should be noted that a known specific code may be used instead of all 0 and all 1. A padding code for a cell that does not transmit a paging signal may be a random value. In this case, a random value is derived for each cell and padded. In this way, in the mobile terminal, the signals transmitted from the cells that do not transmit the paging signal are canceled each other due to different random signals, and the paging signal components transmitted from the cell that transmits the paging signal are relative to each other. Therefore, it is possible to reduce paging signal reception errors in the correlation calculation.

  A paging transmission cell identification code for identifying a cell that transmits a paging signal and a cell that does not transmit the paging signal may be used. The paging transmission cell identification code may be an orthogonal or pseudo-orthogonal code. Further, it may be a scrambling code or a spreading code. FIG. 26 is an explanatory diagram showing a method of using a paging transmission cell identification code. The base station multiplies the paging signal by the mobile terminal identification code, performs coding processing such as CRC addition, encoding, rate matching, and MCS (Modulation Coding Scheme) reflection, and multiplies the paging transmission cell identification code. . As a paging transmission cell identification code, a spreading code for a paging signal transmission cell is used in a cell that transmits a paging signal. In a cell that does not transmit a paging signal, a spreading code for a paging signal non-transmitting cell is used. The spreading code for the paging signal transmission cell and the spreading code for the paging signal non-transmission cell, which are paging transmission cell identification codes, are set as orthogonal codes. The result of multiplying these paging transmission cell identification codes is assigned to each control information element unit and connected to each mobile terminal that is receiving an incoming call. On the other hand, a mobile terminal receiving or trying to receive an MBMS service transmitted from a cell in a certain MBSFN area or MBSFN synchronization area receives a PMCH, DPCH, or main PMCH to which a paging signal is mapped. Then, demodulation processing, despreading processing, etc. are performed to divide the area into control information element units. The divided area of the control information element unit is despread by the paging signal transmission cell spreading code. In the same physical area, the cells that transmit the paging signal and the cells that do not transmit are multiplied and transmitted by orthogonal spreading codes, so by performing despreading using the spreading code for the paging signal transmission cell, It is possible to eliminate the influence of a signal from a cell that does not transmit a paging signal, and a reception error can be reduced.

  The despread data is subjected to processing such as decoding, and blind detection is performed using the mobile terminal identification code. If the correlation calculation result is greater than a certain threshold, it is determined that there is paging for the mobile terminal, and a paging incoming operation is started by a paging signal. If it is less than a certain threshold value, it is determined that there is no paging for the terminal itself, and the process shifts to reception of MBMS related information, or shifts to the intermittent reception operation if it is not necessary to receive MBMS related information. Each paging transmission cell identification code may be determined in advance, or may be notified by broadcast information of an MBMS dedicated cell or broadcast information of a unicast cell. In this way, by multiplying the cells that transmit the paging signal and the cells that do not transmit by orthogonal spreading codes and despreading on the receiving side, the influence of the signal from the cell that does not transmit the paging signal is eliminated, and the paging signal Can be extracted with a low reception error. In the present invention, the order of multiplying the mobile terminal identification code and the paging transmission cell identification code may be reversed. When the mobile terminal identification code is multiplied later, the mobile terminal first determines whether there is a paging signal for the mobile terminal by performing a correlation operation with an identification number unique to the mobile terminal first. The advantage is that this is possible.

  In the present embodiment, each cell may be a code that does not transmit a paging signal with a padding code or a paging transmission cell identification code as an initial setting. Only when a paging occurrence notification is received from the MME, MCE or MBMS-GW, the cell sends a paging signal and a paging transmission cell identification code to only the mobile terminal that has received the notification. A code to be transmitted may be used. This eliminates the need to send a notification that no paging occurs from the MME, MCE, or MBMS-GW to each cell, thereby reducing the amount of signaling.

  By configuring as in the present embodiment, it is possible to provide a cell that transmits a paging signal and a cell that does not transmit, and even when the MBSFN area or the MBSFN synchronization area is geographically wide, It becomes possible to limit the cell which transmits a paging signal to the cell in which a mobile terminal exists, and the nearby cell. Even when the cell that transmits the paging signal is limited to the cell where the mobile terminal exists and the neighboring cell, the reception quality of the desired paging signal deteriorates due to the different signal transmitted from the cell that does not transmit the paging signal. An effect is obtained that a paging signal can be received without causing it to occur. In particular, an effect that a high-quality paging signal can be received is obtained for a mobile terminal that exists near the boundary between a cell that transmits a paging signal and a cell that does not transmit a paging signal. Further, for example, when a paging signal is transmitted only to a cell in one or a plurality of MBSFN areas that are geographically close to the tracking area of a unicast cell, the MME that has received the paging request It is not necessary to transmit a paging request signal to all corresponding MCEs, and it is sufficient to transmit a paging request signal only to the MCE that controls the MBSFN area. An MCE that has received a paging request signal transmits a paging signal to a cell in an MBSFN area controlled by the MCE, and an MCE that does not receive a paging request signal does not transmit a paging signal in an MBSFN area controlled by the MCE. It becomes possible. Therefore, it is possible to reduce the amount of signaling between the MME and the MCE. Furthermore, by limiting the cell that transmits the paging signal to the cell in which the mobile terminal exists and the neighboring cell, the physical resources used for the paging signal transmission of a certain mobile terminal can be transferred to other mobile terminals at geographically distant locations. It can be used for paging signal transmission to a terminal, and the efficiency of radio resources can be improved.

It is explanatory drawing which shows the structure of the communication system of a LTE system. It is explanatory drawing which shows the structure of the communication system of a LTE system. FIG. 2 is an explanatory diagram showing a configuration of a radio frame used in an LTE communication system. It is explanatory drawing which shows the structure of a MBSFN (Multimedia Broadcast multicast service Single Frequency Network) frame. It is explanatory drawing explaining the physical channel used with the communication system of a LTE system. It is explanatory drawing explaining the transport channel used with the communication system of a LTE system. It is explanatory drawing explaining the logical channel used with the communication system of a LTE system. It is explanatory drawing explaining the relationship between a MBSFN synchronous area and a MBSFN area. It is explanatory drawing explaining the logical structure (Logical Architecture) of E-MBMS. It is explanatory drawing explaining the architecture (Architecture) of E-MBMS. It is explanatory drawing which shows the structure of the physical multicast channel provided for every MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area. It is explanatory drawing which shows the structure of the physical multicast channel provided for every MBSFN (Multimedia Broadcast multicast service Single Frequency Network) area. It is explanatory drawing which shows the structure of the physical multicast channel (PMCH) which carried the paging signal. It is explanatory drawing which shows the method of mapping a paging signal to the area | region on a physical multicast channel. It is explanatory drawing which shows an example of the method of mapping a paging signal to the physical area | region where the paging signal on a physical multicast channel (PMCH) is carried. It is explanatory drawing which shows the structure of PMCH provided for every MBSFN area. It is explanatory drawing which shows the structure of the physical channel only for paging transmitted in multicell within an MBSFN area. It is explanatory drawing which shows the structure of a MBSFN sub-frame. It is explanatory drawing which shows the method of mapping a paging signal to a paging exclusive channel (DPCH). It is explanatory drawing which shows the method of mapping a paging signal to a paging exclusive channel (DPCH). It is explanatory drawing which shows the structure of the physical channel (main PMCH) transmitted by multicell within a MBSFN synchronous area. It is explanatory drawing shown about the structure of the radio | wireless frame with which main PMCH is transmitted. It is explanatory drawing shown about the structure of the radio | wireless frame by which main PMCH is transmitted within the same sub-frame as the synchronization channel SCH. It is explanatory drawing which shows the structure of main PMCH which provided the area | region for paging signals. It is explanatory drawing which shows the method of transmitting a paging signal to the one part cell in a MBSFN area or a MBSFN synchronous area. It is explanatory drawing which shows the example of the code for the padding for every cell provided with the cell which does not transmit a paging signal. It is explanatory drawing which shows the method of using the code for paging transmission cell identification. It is explanatory drawing which shows the mapping method in the case of putting MBMS relevant information and a paging signal on a multicast control channel (MCCH) as an information element. It is explanatory drawing which shows the mapping method in the case of multiplexing the logical channel PCCH with the logical channels MTCH and MCCH, and mounting on the transport channel MCH. FIG. 4 is an explanatory diagram showing a mapping method when the logical channel PCCH is placed on the transport channel PCH, the logical channels MTCH and MCCH are multiplexed and placed on the transport channel MCH, and the PCH and MCH are multiplexed and placed on the physical multicast channel. is there. It is explanatory drawing which shows the mapping method in the case where a paging signal is put on the transport channel PCH on the logical channel PCCH, the logical channels MTCH and MCCH are multiplexed and put on the transport channel MCH, and the PCH is put on the physical channel dedicated to paging. . It is explanatory drawing which shows the mapping method at the time of providing main PMCH as a physical channel common to a MBSFN synchronous area.

Explanation of symbols

101 mobile terminals, 102 base stations,
103 MME (Mobility Management Entity),
104 S-GW (Serving Gateway)

Claims (6)

A communication system that uses an OFDM (Orthogonal Frequency Division Multiplexing) scheme as a downlink access scheme and an SC-FDMA (Single Career Frequency Division Multiple Access) scheme as an uplink access scheme, and is a one-to-many broadcast communication with respect to a mobile terminal In a mobile communication system capable of transmitting broadcast type data providing MBMS (Multimedia Broadcast Multicast Service) as a service and transmitting one-to-one type individual communication data to the mobile terminal,
The communication system includes a unicast cell that is a cell in which a mobile terminal can transmit and receive the dedicated communication data, an MBMS dedicated cell that allows the mobile terminal to receive the broadcast type data but cannot transmit and receive the dedicated communication data, The unicast / MBMS mixed cell can provide both unicast cell and MBMS dedicated cell services, and the MBMS dedicated cell can transmit the broadcast data in synchronization with a plurality of base stations. Configure the MBSFN (Multimedia Broadcast multicast service Single Frequency Network) synchronization area
A mobile communication system, wherein a paging signal for the mobile terminal is synchronously transmitted in a plurality of cells included in the MBSFN synchronization area while receiving the broadcast type data transmitted from the MBMS dedicated cell. The mobile communication system according to claim 1, wherein the paging signal is transmitted by a physical channel dedicated for paging provided in a downlink for a mobile terminal from a cell included in the MBSFN synchronization area. The paging signal is transmitted on a multicast control channel, which is a common channel for controlling MBMS transmission, provided in a downlink from a cell included in the MBSFN synchronization area to a mobile terminal. Mobile communication system. The mobile unit according to claim 2, wherein the paging-dedicated physical channel is multiplexed by selectively using a time division multiplexing method and a code division multiplexing method in accordance with cells constituting the MBSFN synchronization area. Communications system. The mobile communication system according to claim 3, wherein the multicast control channel includes a paging signal and MBMS control information for controlling MBMS transmission. The mobile communication system according to claim 5, wherein the multicast control channel further includes identification information indicating whether the MBMS control information has been changed.

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