RETRANSMISSION NODE IN A MOBILE COMMUNICATION NETWORK, NON TRANSIENT COMPUTER-READABLE MEDIUM, AND M

专利摘要:
relay node in a mobile communication network, non-transient computer readable medium, and, method performed by a relay node in a communication network to receive a radio signal from a base station and to forward the signal to a mobile station a relay node in a mobile communication network for receiving a radio signal from a base station and for forwarding the signal to a mobile station is disclosed. the relay node includes a control unit that manages first information corresponding to the link between the relay node and the mobile station, and a transmitter that directly transmits the first information to another relay node in the mobile communication network. the relay node includes a receiver which receives, from the other relay node, second information corresponding to a link between the other relay node and another mobile station. the control unit controls resources used to communicate with the mobile station based on the first information corresponding to the connection between the relay node and the mobile station and the second information corresponding to the connection between the other relay node and another mobile station .
公开号:BR112012006048B1
申请号:R112012006048-1
申请日:2010-07-29
公开日:2021-08-24
发明作者:Ryo Sawai
申请人:Sony Corporation；
IPC主号:

专利说明:

CROSS REFERENCES TO RELATED ORDERS
[0001] This application claims priority benefit under 35 USC 119 of Japanese Patent Application 2009-220881, filed September 25, 2009, and Japanese Patent Application 2010-040227, filed February 25, 2010, which entire contents of each are hereby incorporated by reference. FIELD OF THE INVENTION
[0002] The present invention concerns a communication system, a relay node, a user equipment and a base station. FUNDAMENTALS OF THE INVENTION
[0003] A relay technique is standardized in IEEE (Institute of Electrical and Electronics Engineers) 802.16j. Additionally, also in 3GPP (3rd Generation Partnership Project) LTE-A (Long Term Evolution - Advanced), a technique that uses a relay node (RN) is actively studied in order to improve the throughput of an equipment (UE) located at the edge of the cell.
[0004] The relay node receives a transmitted signal from a base station, amplifies the signal and transmits the amplified signal to user equipment on the downlink. A retransmission as it is at the relay node guarantees a higher signal-to-noise ratio compared to direct transmission of a signal from the base station to the user equipment. Also, the relay node retransmits a transmitted signal from the user equipment to the base station on the uplink, thereby maintaining a high signal-to-noise ratio. The relay node is disclosed in the following non-patent literatures 1 to 3, for example.
[0005] The transmit power of a signal transmitted by the user equipment near the cell edge is sufficiently small. Thus, if there is no relay node, interference with the adjacent cell is not a significant problem. CITATION LIST NON-PATENT LITERATURE
[0006] [NPL 1] R1-090015, "Consideration on Relay.ppt", China Potevio, CATT, January 2009.
[0007] [NPL 2] R1-090065, "Joint analog network coding and Relay", Alcatel-Lucent, January 2009.
[0008] [NPL 3] R1-091803, "Understanding on Type 1 and Type 2 Relay", Huawei, May 2009. SUMMARY OF THE INVENTION TECHNICAL PROBLEM
[0009] However, if relay nodes belonging to different base stations are located near each edge of the cell, the interference between cells due to each relay node will be a more significant problem since relay nodes transmit signals at the power of higher transmission than the user equipment.
[00010] Considering the above problem, it can be effective for each relay node to exchange information through each base station to avoid interference based on the exchanged information. However, it takes time to exchange information through the base station, and it is considered difficult to deal quickly with a change in communication state.
[00011] In light of the above, it is desirable to provide a communication system, a relay node, a user equipment and a base station that are new and better, and with which one or more of a small size base station medium, such as relay nodes, can communicate directly. SOLUTION OF THE PROBLEM
[00012] An exemplary embodiment of the specification is directed to a relay node in a mobile communication network to receive a radio signal from a base station and to forward the signal to a mobile station. The relay node including a control unit that manages the first information corresponding to the link between the relay node and the mobile station and a transmitter that directly transmits the first information to another relay node in the mobile communication network. The relay node including a receiver which receives, from the other relay node, second information corresponding to a link between the other relay node and another mobile station. The control unit controlling resources used to communicate with the mobile station based on the first information corresponding to the connection between the relay node and the mobile station and the second information corresponding to the connection between the other relay node and another mobile station .
[00013] The relay node can be configured to determine that the link between the other relay node and another mobile station can interfere with the link between the relay node and the mobile station based on the first information corresponding to the link between the relay node and the mobile station and in the second information corresponding to the connection between the other relay node and another mobile station. The control unit may be configured to modify the resources used to communicate with the mobile station based on the determination that the link between the other relay node and another mobile station may interfere with the link between the relay node and the mobile station.
[00014] The receiver can be configured to receive resource allocation information from the base station which indicates communication resources assigned to the relay node to communicate directly with the other relay node and to directly transmit the first information to the other one. relay node in the mobile communication network based on the resource allocation information received from the base station.
[00015] The relay node may further comprise a relay node detection unit configured to detect the existence of another relay node by detecting a signal transmitted from the other relay node and an interference determination unit configured to determine that the signal detected by the detection unit of the relay node may interfere with the connection between the relay node and the mobile station.
[00016] The detection unit of the relay node can be configured to detect the existence of another relay node based on signals transmitted from another base station to which the other relay node is connected, and the unit The control request a direct communication link with another relay node to another base station.
[00017] The detection unit of the relay node can be configured to detect the existence of another relay node based on signals transmitted from the other relay node, and the control unit requests a direct communication link with o another relay node to the base station to which the relay node is connected.
[00018] The detection unit of the relay node can be configured to detect the existence of another relay node based on signals transmitted from the other relay node, and the control unit requests a direct communication link with o another relay node by transmitting a connection request directly to another relay node.
[00019] The first information corresponding to the connection between the relay node and the mobile station may include at least one of identification information corresponding to the mobile station, of a permissible interference level corresponding to the connection between the relay node and the mobile station , a channel quality indicator (CQI) corresponding to the connection between the relay node and the mobile station, the quality of service information (QoS) corresponding to a required connection quality between the relay node and the mobile station, and of a relay node position.
[00020] Another exemplary embodiment is directed to computer readable media that includes computer program instructions that, when executed by a relay node in a communication network, cause the relay node to perform a method to receive a radio signal from a base station and to route the signal to a mobile station. The method may include managing the first information corresponding to a link between the relay node and the mobile station; directly transmitting the first information to another relay node in the mobile communication network; receiving, from the other relay node, the second information corresponding to a connection between the other relay node and another mobile station; and controlling the resources used to communicate with the mobile station based on the first information corresponding to the connection between the relay node and the mobile station and the second information corresponding to the connection between the other relay node and another mobile station.
[00021] The method may further include determining that the connection between the other relay node and another mobile station may interfere with the connection between the relay node and the mobile station based on the first information corresponding to the connection between the node of the relay and the mobile station and in the second information corresponding to the connection between the another relay node and another mobile station.
[00022] The method may further include modifying the resources used to communicate with the mobile station based on the determination that the link between the other relay node and another mobile station may interfere with the link between the relay node and the mobile station.
[00023] Another exemplary embodiment is directed to the method performed by a relay node in a communication network to receive a radio signal from a base station and forward the signal to a mobile station. The method may include managing, in a control unit of the relay node, the first information corresponding to a link between the relay node and the mobile station; directly transmitting, by a transmitter of the relay node, the first information to another relay node in the mobile communication network; receiving, at a receiver of the relay node, from the other relay node, the second information corresponding to a link between the other relay node and another mobile station; and controlling, in the control unit of the relay node, the resources used to communicate with the mobile station on the basis of the first information corresponding to the connection between the relay node and the mobile station and the second information corresponding to the connection between the other node. relay and to another mobile station.
[00024] The method may further include determining that the connection between the other relay node and another mobile station may interfere with the connection between the relay node and the mobile station based on the first information corresponding to the connection between the node of the relay and the mobile station and in the second information corresponding to the connection between the another relay node and another mobile station.
[00025] The method may further include modifying the resources used to communicate with the mobile station based on the determination that the link between the other relay node and another mobile station may interfere with the link between the relay node and the mobile station. BRIEF DESCRIPTION OF THE DRAWINGS
[00026] Figure 1 is an explanatory view showing a configuration of the communication system 1 according to an embodiment of the present invention.
[00027] Figure 2 is an explanatory view that shows an example of resource allocation in the case of using the same frequency in UL and DL.
[00028] Figure 3 is an explanatory view that shows an example of resource allocation in the case of using different frequencies in UL and DL.
[00029] Figure 4 is an explanatory view showing an example of a DL radio frame format.
[00030] Figure 5 is an explanatory view showing an example of a UL radio frame format.
[00031] Figure 6 is an explanatory view that shows a connection processing sequence.
[00032] Figure 7 is an explanatory view that shows an illustrative example of MBSFN transmission/reception processing.
[00033] Figure 8 is an explanatory view that shows an example of the frequency allocation in each cell.
[00034] Figure 9 is an explanatory view that shows an example of an interference case to be processed in the first embodiment of the present invention.
[00035] Figure 10 is a functional block diagram showing a configuration of a 20 user equipment.
[00036] Figure 11 is a functional block diagram showing a configuration of the relay node 30.
[00037] Figure 12 is a functional block diagram showing a configuration of base station 10.
[00038] Figure 13 is a functional block diagram showing a configuration of management server 16.
[00039] Figure 14 is a sequence graph showing an operation by the first embodiment of the present invention.
[00040] Figure 15 is a functional block diagram showing a configuration of the relay node 30' according to the second embodiment of the present invention.
[00041] Figure 16 is a sequence graph showing a flow for connection processing by the second embodiment of the present invention.
[00042] Figure 17 is a sequence graph showing a flow for connection processing by the second embodiment of the present invention.
[00043] Figure 18 is a sequence graph showing a flow for connection processing by the second embodiment of the present invention.
[00044] Figure 19 is a sequence graph showing a flow for connection processing by the second embodiment of the present invention.
[00045] Figure 20 is an explanatory view that shows an example of heterogeneous network architecture.
[00046] Figure 21 is an explanatory view that shows an overview of a small to medium sized base station.
[00047] Figure 22 is an explanatory view showing an exemplary configuration of a small to medium sized base station.
[00048] Figure 23 is an explanatory view that shows an interference model in a heterogeneous network.
[00049] Figure 24 is an explanatory view that shows an example of transfer interference avoidance.
[00050] Figure 25 is an explanatory view that shows an example of interference avoidance by beamforming.
[00051] Figure 26 is an explanatory view that shows an example of interference avoidance by controlling the transmission power.
[00052] Figure 27 is an explanatory view that shows a situation where small to medium sized base stations exchange information directly.
[00053] Fig. 28 is an explanatory view showing a sequence for a plurality of small to medium sized base stations to exchange information. DESCRIPTION OF MODALITIES
[00054] In the following, preferred embodiments of the present invention will be described in detail in relation to the accompanying drawings. Note that, in this specification and the accompanying drawings, structural elements that have substantially the same function and structure are denoted with the same reference numerals, and repeated explanation of these structural elements is omitted.
[00055] Additionally, in this specification and in the drawings, each of a plurality of structural elements having substantially the same function is distinguished by affixing a different alphabetical letter to the same reference number in some cases. For example, a plurality of structural elements that have substantially the same function are distinguished as user equipment 20A, 20B and 20C when necessary. However, when there is no particular need to distinguish between a plurality of structural elements with the same function, they are denoted by the same reference number. For example, when there is no particular need to distinguish between user equipment 20A, 20B and 20C, they are simply referred to as user equipment 20.
[00056] Preferred embodiments of the present invention will be described below in the following order:1. Communication System Basic Configuration (Example of Resource Allocation on Each Link) (Example of Radio Frame Format) (Connection Processing Sequence) (MBSFN)(Example of Frequency Allocation on Each Cell)2. First Mode(User Equipment Setup)(Relay Node Setup)(Base Station Setup)(Management Server Setup)(First Mode Operation)3. Second Mode(Relay Node Configuration)4. Other Applications of the Invention5. summary <1. Communication System Basic Configuration>
[00057] A basic configuration of a communication system 1 according to an embodiment of the present invention is described below in relation to figures 1 to 8. Figure 1 is an explanatory view showing a configuration of the communication system 1 according to with an embodiment of the present invention. Referring to Figure 1, the communication system 1 according to the embodiment of the present invention includes base stations 10A and 10B, a backbone network 12, user equipment 20A, 20B and 20X and relay nodes 30A and 30B.
[00058] The base station 10 manages the communication between the relay node 30 and the user equipment 20 located inside a cell formed by the base station 10. For example, the base station 10A manages the scheduling information for communication with the 20X user equipment located inside the cell and communicates with the 20X user equipment according to the scheduling information. Additionally, the base station 10A manages the scheduling information for communication with the relay node 30A located inside the cell and the scheduling information for communication between the relay node 30A and the user equipment 20A.
[00059] Note that scheduling information management can be performed cooperatively by base station 10 and relay node 30, can be performed cooperatively by base station 10, relay node 30 and user equipment 20, or it may be performed by the relay node 30.
[00060] The relay node 30 relays the communication between the base station 10 and the user equipment 20 in accordance with the scheduling information managed by the base station 10. Specifically, the relay node 30 receives a signal transmitted from the station. base 10 and transmits the amplified signal to user equipment 20 by using frequency/time according to scheduling information on downlink. With a retransmission like this at relay node 30, a signal to noise ratio is higher compared to direct transmission of a signal from base station 10 to user equipment 20 near the edge of the cell.
[00061] Likewise, also on the uplink, the relay node 30 retransmits a signal transmitted from the user equipment 20 to the base station 10 according to the scheduling information managed by the base station 10, thereby maintaining a high rate of signal by noise. Despite the case that only relay node 30A exists in the cell formed by base station 10A, a plurality of relay nodes 30 can exist in the cell formed by base station 10A.
[00062] Type 1 and Type 2 are proposed as the types of relay nodes 30. Type 1 relay node 30 has an individual cell ID and allows managing its own cell. Thus, the Type 1 relay node 30 operates in such a way that it is recognized as the base station 10 by the user equipment 20. However, the Type 1 relay node 30 does not operate completely autonomously, and the node relay 30 performs relay communication in the range of resources allocated by base station 10.
[00063] On the other hand, Relay node 30 of Type 2, unlike Type 1, does not have an individual cell ID and supports direct communication between base station 10 and user equipment 20. For example, a technique of retransmission type transmission that uses cooperative retransmission or network coding is being studied. The following Table 1 shows characteristics of Type 1 and Type 2 under study.

[00064] The user equipment 20 communicates with the base station 10 directly or through the relay node 30 according to the scheduling information managed by the base station 10. Data transmitted or received by the user equipment 20 may be voice data, music data such as music, lectures or radio programs, still image data such as photographs, documents, pictures or graphics, or video data such as movies, television programs, video programs, game images or congeners. Additionally, user equipment 20 may be an information processing device with a radio communication function, such as a cell phone or a personal computer (PC).
[00065] A management server 16 is connected to each base station 10 through backbone network 12. The management server 16 functions as a mobile management entity (MME). Additionally, the management server 16 can function as a server communication port. The management server 16 receives management information indicating the state of the cell formed by each base station 10 from the respective base stations 10 and controls communication in the cell formed by each base station 10 based on the management information. The role of the management server 16 can be incorporated into a plurality of physically separate structures in a distributed manner. (Example of Resource Allocation in Each Connection)
[00066] Resource allocation on each link is described below. In the following description, a communication path between base station 10 and relay node 30 is referred to as a relay link, a communication path between relay node 30 and user equipment 20 is referred to as an access link. and a direct communication path between base station 10 and user equipment 20 is referred to as a direct link. Additionally, a communication path towards base station 10 is referred to as UL (uplink) and a communication path towards user equipment 20 is referred to as DL (downlink). Communication on each link is based on OFDMA.
[00067] The relay node 30 separates the relay link and the access link by frequency or time in order to avoid interference between the relay link and the access link. For example, the relay node 30 can separate the relay link and the access link in the same direction by TDD (Time Division Duplexing) using a common frequency.
[00068] Figure 2 is an explanatory view that shows an example of resource allocation in the use case of the same frequency in UL and DL. Referring to Fig. 2, a radio frame is made up of subframes 0 to 9. Additionally, in the example shown in Fig. 2, the relay node 30 recognizes subframes 8 and 9 as resources for DL of the access link according to a direction of base station 10 and therefore retransmits a signal transmitted from base station 10 to user equipment 20 using subframes 8 and 9.
[00069] Note that PSC (Primary Sync Channel) and SSC (Secondary Sync Channel), which are downlink synchronous signals, or PBCH (Physical Broadcast Channel) are allocated in subframes 0 and 5. Additionally, a channel of radiocall is allocated in subframes 1 and 6.
[00070] Figure 3 is an explanatory view that shows an example of resource allocation in the case of using different frequencies in UL and DL. Referring to Figure 3, a frequency f0 is used for DL and a frequency f1 is used for UL. Additionally, in the example shown in Fig. 3, the relay node 30 recognizes subframes 6 to 8 of frequency f0 as resources for DL of the access link according to a direction of base station 10 and therefore retransmits a signal transmitted from from base station 10 to user equipment 20 using subframes 6 to 8 of frequency f0.
[00071] Note that PSC and SSC, which are downlink synchronous signals, are allocated in subframes 0 and 5 of frequency f0 (for DL), and a paging channel is allocated in subframes 4 and 9. (Example of Radio Frame Format)
[00072] Detailed examples of frame format of DL radio frame and UL radio frame are described below in relation to figures 4 and 5.
[00073] Figure 4 is an explanatory view showing an example of the DL radio frame format. The DL radio frame is made up of subframes 0 to 9, each subframe is made up of two 0.5ms intervals and each 0.5ms interval is made up of seven OFDM (Orthogonal Frequency Division Multiplexing) symbols.
[00074] As shown in figure 4, a control channel such as PCFICH (Physical Control Format Indicator Channel), PHICH (Physical Hybrid ARQ Indicator Channel) or PDCCH (Physical Downlink Control Channel) is present in the first to third OFDM symbols in the header of each subframe.
[00075] Each of the exposed channels contains the following information as an example.PCFICH: The number of PDCCH symbols related to Layer 1 and Layer 2;PHICH: ACK / NACK for PUSCH;
[00076] PDCCH: Downlink Control Information. Scheduling information (format such as modulation scheme or coding rate) of PDSCH / PUSCH.
[00077] Additionally, a resource block (1RB), which is a minimum resource allocation unit, is constituted by six or seven OFDM symbols and 12 subcarriers. A demodulation reference (reference signal) is present in a part of the resource block.
[00078] Additionally, SSC, PBCH and PSC are present in subframes 0 and 5. A free space in the radio frame shown in figure 4 is used as PDSCH (Physical Downlink Shared Channel).
[00079] Figure 5 is an explanatory view showing an example of the UL radio frame format. Like the DL radio frame, the UL radio frame is made up of subframes 0 through 9, each subframe is made up of two 0.5ms intervals and each 0.5ms interval is made up of seven OFDM symbols.
[00080] As shown in Fig. 5, a demodulation reference (reference signal) is present in each of the 0.5 ms intervals, and a CQI measurement reference is present in a distributed manner. The base station 10 or the relay node 30 at the receiving terminal performs channel estimation by using the demodulation reference and demodulates a received signal in accordance with the result of the channel estimation. Additionally, the base station 10 or the relay node 30 at the receiving terminal measures the measurement reference CQI and thereby acquires CQI with the relay node 30 or with user equipment 20 at the transmitting terminal.
[00081] Additionally, a free space in the radio frame shown in figure 5 is used as PUSCH (Physical Uplink Shared Channel). Note that upon receipt of a request for a CQI report, the user equipment 20 or the relay node 30 transmits the CQI report using PUSCH. (Connection Processing Sequence)
[00082] A connection processing sequence between the relay node 30 or the user equipment 20 and the base station 10 is described below in relation to figure 6.
[00083] Figure 6 is an explanatory view that shows a connection processing sequence. Referring to Fig. 6, the relay node 30 or the user equipment 20 transmits the RACH (Random Access Channel) preamble to the base station 10 (S62). Receiving the RACH preamble, the base station 10 acquires TA information (Synchronization Advance) and transmits the TA information along with the resource information allocated to relay node 30 or user equipment 20 (S64). For example, in the case where the RACH preamble transmit timing is known, the base station 10 can acquire a difference between the transmit timing and the receive timing from the RACH preamble as the TA information.
[00084] Thereafter, relay node 30 or user equipment 20 transmit RRC connection request to base station 10 by using the resources indicated by the allocated resource information (S66). Receiving the RRC connection request, the base station 10 transmits RRC connection resolution which indicates a transmission source of the RRC connection request (S68). In this way, the relay node 30 or the user equipment 20 can confirm whether the base station 10 has received the RRC connection request.
[00085] Then, the base station 10 transmits the connection request which indicates that the relay node 30 or the user equipment 20 is making a service request to the management server 16 which functions as MME (S70). Upon receiving the connection request, the management server 16 transmits the information to be defined to the relay node 30 or to the user equipment 20 as connection configuration (S72).
[00086] Then, the base station 10 transmits the RRC connection configuration to the relay node 30 or to the user equipment 20 based on the connection configuration coming from the management server 16 (S74), and the relay node 30 or the 20 user equipment configures the connection. Thereafter, relay node 30 or user equipment 20 transmit RRC connection completion which indicates connection setup completion to base station 10 (S76).
[00087] In this way, the connection between relay node 30 or user equipment 20 and base station 10 is completed, and communication becomes available. The above-described connection processing sequence is for illustration only, and the relay node 30 or the user equipment 20 and the base station 10 may be connected by another sequence.(MBSFN)
[00088] In the following, MBSFN (Single Frequency Multimedia Broadcast Network) transmission, which is performed by the base station 10, and an exemplary operation of the relay node 30 in response to the MBSFN transmission are described.
[00089] MBSFN is the mode in which a plurality of base stations 10 transmit data simultaneously to the broadcast mode on the same frequency. Therefore, in MBSFN, the Type 1 relay node 30, which operates virtually as a base station, transmits a control channel to DL or the like by using the same frequency as that of the base station 10. A specific stream of transmission processing / MBSFN reception is described below in relation to Figure 7.
[00090] Figure 7 is an explanatory view that shows an illustrative example of MBSFN transmission/reception processing. First, as shown in Fig. 7, base station 10 and relay node 30 transmit PDCCH simultaneously. Base station 10 transmits, after PDCCH, PDSCH to user equipment 20 and R-PDCCH to control a retransmission. After R-PDCCH, base station 10 transmits PDSCH to relay node 30 (relay target data). A no-transmission period arrives after PDSCH for the relay node 30.
[00091] The relay node 30 receives, after transmitting PDCCH, PDSCH (relay target data) from the base station 10 subsequent to a switching period for reception processing. Then, relay node 30 switches receive processing to transmit processing in the non-transmission period that arrives after PDSCH (relay target data) of base station 10. Additionally, in the next step, relay node 30 adds PDCCH on the decoded PDSCH (retransmission target data) and then transmits the data to the user equipment 20.
[00092] In this way, existing user equipment that does not consider the existence of relay node 30 can take advantage of retransmission by relay node 30 without confusion. (Example of Frequency Allocation in Each Cell)
[00093] An example of frequency allocation in each cell in the case where a plurality of cells are adjacent is described below.
[00094] Figure 8 is an explanatory view that shows an example of the frequency allocation in each cell. In the case where each cell consists of three sectors, the frequencies f1 to f3 are allocated in the respective sectors as shown in figure 8, thus suppressing the interference of frequencies in the cell boundary. Such an allocation is particularly effective in a densely populated area with heavy traffic.
[00095] In LTE-A, in order to achieve high end-to-end throughput, several new techniques, such as spectrum aggregation, network MIMO, uplink multiuser MIMO and retransmission technique, are being studied. Therefore, with the advent of unprecedented mobile applications with high throughput, there is a possibility that frequency resource exhaustion will also appear as a problem in a suburban area. Additionally, in the introduction of LTE-A, it is highly possible that the installation of relay node 30 is activated for the purpose of achieving infrastructure development at low cost.
[00096] If the relay nodes 30 that belong to different base stations 10 are located close to each of the cell edges, the interference between cells caused by each of the relay nodes 30 will be a more significant problem, since the node relay 30 transmits a signal at higher transmit power than user equipment 10.
[00097] In light of the foregoing, the first embodiment and the second embodiment of the present invention will be described as follows. Each of the first embodiment and the second embodiment of the present invention includes additional features in addition to configuring the communication system 1 according to an embodiment of the present invention. <2. First Mode>
[00098] Figure 9 is an explanatory view that shows an example of an interference case to be processed in the first embodiment of the present invention. As illustrated in Figure 9, if user equipment 20A transmits a signal to relay node 30A via the UL of the access link at the same time as relay node 30B transmits a signal to user equipment 20B via the DL of the access link, both signals interfere with relay node 30B.
[00099] If the relay node 30A transmits a signal to the base station 10A via the relay link UL at the same time as the user equipment 20B transmits a signal to the relay node 30B via the access link UL, both the signals interfere with relay node 30B.
[000100] According to the first embodiment of the present invention, it is possible that such interference in relation to the relay node 30 is prevented by the exchange of information held by the relay node 30A and by the relay node 30B that belong, respectively, to different base stations 10. Next, the first mode will be described in detail in relation to figures 10 to 14. (Configuration of User Equipment)
[000101] Figure 10 is a functional block diagram showing a configuration of the user equipment 20. With respect to figure 10, the user equipment 20 includes a plurality of antennas 220a to 220n, an analog processing unit 224, a AD / DA conversion unit 228 and a digital processing unit 230.
[000102] Each of the plurality of antennas 220a to 220n receives a radio signal from the base station 10 or relay node 30, acquires an electrical signal at high frequency and supplies the signal at high frequency to the analog processing unit 224 Additionally, each of the plurality of antennas 220a through 220n transmits a radio signal to base station 10 or relay node 30 based on a high frequency signal supplied from analog processing unit 224. 220a to 220n, the user equipment 20 is capable of performing MIMO (Multiple Inputs and Multiple Outputs) communication or diversity communication.
[000103] The analog processing unit 224 converts the high frequency signal supplied from the plurality of antennas 220a up to 220n into a baseband signal by performing analog processing such as amplification, filtering and downconversion. Additionally, the analog processing unit 224 converts a baseband signal supplied from the AD/DA conversion unit 228 into a high frequency signal.
[000104] The AD / DA conversion unit 228 converts the baseband signal supplied from the analog processing unit 224 from analog to digital and supplies the digital signal to the digital processing unit 230. Additionally, the AD / conversion unit DA 228 converts the baseband signal supplied from the digital processing unit 230 from digital to analogue and supplies the analogue signal to the analogue processing unit 224.
[000105] The digital processing unit 230 includes a synchronous unit 232, a decoder 234, an encoder 240 and a control unit 242. The synchronous unit 232, the decoder 234, the encoder 240 and the like, together with the plurality of antennas 220a to 220n, the analog processing unit 224 and the AD/DA conversion unit 228 function as a communication unit to communicate with the base station 10 or the relay node 30.
[000106] A synchronous signal, such as PSC or SSC, transmitted from base station 10 or relay node 30 is supplied to synchronous unit 232 from AD/DA conversion unit 228, and synchronous unit 232 performs processing radio frame synchronous based on the synchronous signal. Specifically, the synchronous unit 232 synchronizes the radio frame by calculating a correlation between the synchronous signal and a known sequence pattern and detecting a peak of the correlation.
[000107] The decoder 234 decodes the baseband signal supplied from the AD/DA conversion unit 228 and obtains received data. Decoding may include MIMO reception processing and OFDM demodulation processing, for example.
[000108] Encoder 240 encodes transmission data, such as PUSCH, and supplies the encoded data to AD/DA conversion unit 228. Encoding may include MIMO transmission processing and OFDM modulation processing, for example.
[000109] The control unit 242 controls the entire operation of the user equipment 20, such as transmission processing, reception processing and connection processing with the relay node 30 or with the base station 10. For example, the user equipment 20 performs transmit processing and receive processing by using the resource block allocated by base station 10 based on control of control unit 242. Note that control unit 242 controls transmission processing in accordance with a specified transmission parameter by the base station 10 or by the relay node 30. For example, when the base station 10 specifies a TPC (Transmission Power Control) parameter of the user equipment 20 by the PDCCH, the control unit 242 controls the transmission processing accordingly with the TPC parameter specified by base station 10.
[000110] Additionally, when the base station 10 or the relay node 30 makes a request for CQI reporting to the user equipment 20 by the PDCCH, the digital processing unit 230 measures the channel quality (e.g., receive power) by using the demodulation reference transmitted from the base station 10 or the relay node 30. The control unit 242 generates the CQI report based on the measurement result and supplies the generated CQI report to the encoder 240. CQI report is transmitted to base station 10 or relay node 30 using PUSCH. (Relay Node Configuration)
[000111] A configuration of relay node 30 is described below in relation to figure 11.
[000112] Figure 11 is a functional block diagram showing a configuration of the relay node 30. Referring to figure 11, the relay node 30 includes a plurality of antennas 320a to 320n, an analog processing unit 324, a AD / DA conversion unit 328 and a digital processing unit 330.
[000113] Each of the plurality of antennas 320a to 320n receives a radio signal from base station 10 or user equipment 20, acquires a high frequency electrical signal and supplies the high frequency signal to analog processing unit 324 Additionally, each of the plurality of antennas 320a through 320n transmits a radio signal to base station 10 or user equipment 20 based on a high frequency signal supplied from analog processing unit 324. 320a through 320n, relay node 30 is capable of performing MIMO communication or diversity communication.
[000114] The analog processing unit 324 converts the high frequency signal supplied from the plurality of antennas 320a to 320n into a baseband signal by performing analog processing such as amplification, filtering and downconversion. Additionally, the analog processing unit 324 converts a baseband signal supplied from the AD/DA conversion unit 328 into a high frequency signal.
[000115] The AD / DA conversion unit 328 converts the baseband signal supplied from the analog processing unit 324 from analog to digital and supplies the digital signal to the digital processing unit 330. Additionally, the AD / conversion unit DA 328 converts the baseband signal supplied from digital processing unit 330 from digital to analogue and supplies the analogue signal to analogue processing unit 324.
[000116] The digital processing unit 330 includes a synchronous unit 332, a decoder 334, a temporary storage 338, an encoder 340 and a control unit 342. The synchronous unit 332, the decoder 334, the encoder 340 and the like, together with the plurality of antennas 320a to 320n, the analog processing unit 324 and the AD/DA conversion unit 328 function as a receiving unit, a transmitting unit and a relay unit for communicating with the base station 10 or with the user equipment 20.
[000117] A synchronous signal transmitted from the base station 10 is supplied to the synchronous unit 332 of the AD/DA conversion unit 328, and the synchronous unit 332 performs synchronous processing of the radio frame based on the synchronous signal. Specifically, synchronous unit 332 synchronizes the radio frame by calculating a correlation between the synchronous signal and a known sequence pattern and detecting a peak of the correlation.
[000118] Decoder 334 decodes the baseband signal supplied from AD/DA conversion unit 328 and obtains retransmission data with a destination to base station 10 or user equipment 20. Decoding may include MIMO reception processing , OFDM demodulation processing, error correction processing and the like, for example.
[000119] Temporary storage 338 temporarily stores relay data with a destination to base station 10 or user equipment 20, which is obtained by decoder 334. Then, by control of control unit 342, the relay data with a destination to user equipment 20 are read from buffer 338 to encoder 340 in the resource block for DL of the access link. Also, by the control of control unit 342, relay data with a destination to base station 10 is read from temporary storage 338 to encoder 340 in the UL resource block of the relay link.
[000120] Encoder 340 encodes the retransmission data supplied from temporary storage 338 and supplies the encoded data to AD/DA conversion unit 328. Encoding may include MIMO transmission processing and OFDM modulation processing, for example.
[000121] The control unit 342 controls the entire operation of the relay node 30, such as transmission processing, reception processing and connection processing with base station 10 or with user equipment 20. For example, the node of relay 30 performs transmit processing and receive processing by using the resource block allocated by base station 10 based on control by control unit 342.
[000122] The control unit 342 controls the communication to exchange information with the relay node 30B in the adjacent cell by using the resource block allocated by the management server 16. Exchanged information can be, for example, identification information of the equipment. user 20 belonging to each of the relay nodes 30, scheduling information, a permissible interference level, CQI information, QoS information, position-related information or the like. Position-related information may contain GPS-acquired position information, TA information that indicates the distance between the user equipment 20 and the relay node 30, or information that indicates the direction of the user equipment 20. The direction of the user equipment 20 can be acquired by an algorithm that estimates the direction of arrival of a signal transmitted from the user equipment 20 or that performs directional reception.
[000123] Additionally, the control unit 342 need not necessarily control the communication to exchange information with the adjacent relay node 30B by using the aforementioned resource block if a specific logical identifier is added in the resource information indicating the resource block allocated by the management server 16. For example, the control unit 342 may control communication to exchange information as needed or temporarily.
[000124] Additionally, the control unit 342 can control to avoid interference with adjacent cells based on the exchanged information. For example, if the control unit 342 refers to the scheduling information of the relay node 30B and if there is a resource block that overlaps in temporal frequency with the scheduling information of the relay node 30, the control unit 342 may change the use of the resource block. Relay node 30 can also transmit the exchanged information to base station 10, and base station 10 can control to avoid interference. (Base Station Configuration)
[000125] Figure 12 is a functional block diagram showing a configuration of the base station 10. With respect to figure 12, the base station 10 includes a plurality of antennas 120a to 120n, an analog processing unit 124, a unit of AD/DA conversion 128, a digital processing unit 130 and a backbone communication unit 146.
[000126] Each of the plurality of antennas 120a to 120n receives a radio signal from the relay node 30 or user equipment 20, acquires an electrical signal at high frequency and supplies the signal at high frequency to the analog processing unit 124. Additionally, each of the plurality of antennas 120a through 120n transmits a radio signal to relay node 30 or user equipment 20 based on a high frequency signal supplied from analog processing unit 124. With the plurality from 120a to 120n antennas, the base station 10 is capable of performing MIMO communication or diversity communication.
[000127] The analog processing unit 124 converts the high frequency signal supplied from the plurality of antennas 120a up to 120n into a baseband signal by performing analog processing such as amplification, filtering and downconversion. Additionally, the analog processing unit 124 converts a baseband signal supplied from the AD / DA 128 conversion unit into a high frequency signal.
[000128] The AD / DA 128 conversion unit converts the baseband signal supplied from the analog processing unit 124 from analog to digital and supplies the digital signal to the digital processing unit 130. Additionally, the AD / conversion unit DA 128 converts the baseband signal supplied from the digital processing unit 130 from digital to analogue and supplies the analogue signal to the analogue processing unit 124.
[000129] The digital processing unit 130 includes a synchronous unit 132, a decoder 134, an encoder 140, a control unit 142 and a storage unit 144. The synchronous unit 132, the decoder 134, the encoder 140 and the like, together with the plurality of antennas 120a to 120n, the analog processing unit 124 and the AD/DA conversion unit 128 function as a communication unit for communicating with the relay node 30 or with the user equipment 20.
[000130] A synchronous signal transmitted from the user equipment 20 or the relay node 30 is supplied to the synchronous unit 132 from the AD / DA conversion unit 128, and the synchronous unit 132 performs synchronous processing of the radio frame with based on the synchronous signal. The decoder 134 decodes the baseband signal supplied from the AD/DA conversion unit 128 and obtains received data. Decoding can include MIMO receive processing, OFDM demodulation processing, error correction processing, and the like, for example.
[000131] Encoder 140 encodes PDSCH, for example, and supplies the encoded PDSCH to AD/DA 128 conversion unit. Encoding may include MIMO transmission processing and OFDM modulation processing, for example.
[000132] The control unit 142 controls all operation at base station 10, such as transmission processing, reception processing, connection processing with relay node 30 or with user equipment 20, and the management of information from scheduling. For example, the control unit 142 schedules communication on the relay link between base station 10 and relay node 30 and communication on the access link between relay node 30 and user equipment 20.
[000133] Additionally, the control unit 142 stores the management information indicating the state of the cell formed by the base station 10 in the storage unit 144. An example of the management information is as follows: (1) Information related to the position of each relay node 30 and each user equipment 20 belonging to base station 10; (2) ID, QoS class and scheduling information of each relay node 30 and each user equipment 20 belonging to base station 10 ;(3) Communication quality information (eg, CQI information, TPC information, or both) of each relay link and each access link;(4) Permissible interference level (eg, a required SNIR at the minimum rate ) of each user equipment 20 that belongs to base station 10.
[000134] The backbone communication unit 146 communicates with the management server 16 through the backbone network 12. For example, the backbone communication unit 146 transmits the information described in items (1) through (4) At this time, with respect to the foregoing (2), the backbone communication unit 146 can additionally transmit reference counter information for detecting a timing deviation between the station. base 10 and another base station in consideration of the case where base station 10 and another base station operate in an asynchronous manner. (Management Server Configuration)
[000135] Figure 13 is a functional block diagram showing a configuration of the management server 16. With respect to figure 13, the management server 16 includes a communication unit 160, a storage unit 162, a pairing unit 164 and a resource allocation unit 166.
[000136] The communication unit 160 is connected to each base station 10 and has functions of a receiving unit that receives information from each base station 10 and a transmission unit that transmits the information to each base station 10. For example, the communication unit 160 receives the management information described in items (1) to (4) set out from each base station 10. The management information received by the communication unit 160 is stored in the storage unit 162.
[000137] Pairing unit 164 (selection unit) pairs two relay nodes 30 to exchange information with each other by using part of the management information described in items (1) to (4) above, or all of it. Specifically, the pairing unit 164 can pair the two relay nodes 30 that belong to different base stations 10 and that are likely to cause interference with each other. If the communication quality of a certain link does not meet a given criterion (for example, a permissible level of interference), interference is likely to occur on the link. To avoid this, the pairing unit 164 can pair the relay node 30 related to the link whose communication quality does not satisfy a given criterion and the relay node 30 in closest proximity to that relay node 30.
[000138] Additionally, the pairing unit 164 can pair the two relay nodes 30 when the user equipments 20 belonging to the respective relay nodes 30 are in close proximity to each other. Furthermore, the pairing unit 164 can pair the two relay nodes 30 spaced apart at a predetermined distance or less. Furthermore, the pairing unit 164 can pair the two relay nodes 30 using overlapping resource blocks in temporal frequency.
[000139] Note that it is a condition for pairing two relay nodes 30 that the two relay nodes 30 to be paired can obtain resources for exchanging information. Additionally, when there are no relay nodes 30 that are likely to interfere with each other, or when facilities for exchanging information are not obtainable, the pairing unit 164 does not pair and tries to avoid interference in another way.
[000140] The resource allocation unit 166 allocates a resource block to the two paired relay nodes 30 to exchange information. For example, the resource allocation unit 166 allocates a resource block in DL of the access link to the relay node 30 at the information transmission terminal and allocates a resource block in UL of the access link to the relay node 30 at the information receiving terminal. Alternatively, the resource allocation unit 166 may allocate a resource block for UL of the relay link at relay node 30 at the information transmission terminal and allocate a resource block for DL from the relay link at relay node 30 at information receiving terminal.
[000141] Additionally, the resource allocation unit 166 can allocate a resource block to act as the receiving terminal and a resource block to act as the transmit terminal on both relay nodes 30. Thus, both relay nodes 30 can exchange information bidirectionally.
[000142] Note that when the two paired relay nodes 30 are asynchronous, the resource allocation unit 166 can allocate a resource block in such a way that the resource blocks allocated on the respective relay nodes 30 match in time.
[000143] On the other hand, when the base stations 10 to which the two paired relay nodes 30 belong, respectively, are synchronous and they operate in MBSFN with the relay nodes 30 that belong to them, the resource allocation unit 166 can allocate a resource block for DL from the access link in relay node 30 at the information transmitting terminal and allocate a resource block for UL from the access link at relay node 30 at the information receiving terminal. Additionally, the resource allocation unit 166 can allocate a resource block to act as the receiving terminal and a resource block to act as the transmit terminal on both relay nodes 30. Thereby, the two relay nodes 30 can exchange information bidirectionally.
[000144] After the resource block is allocated by the resource allocation unit 166 in the above manner, the communication unit 160 transmits the resource information indicating the resource block allocated to the base stations 10 to which the two relay nodes paired 30 belong, respectively. Additionally, each base station 10 transmits the resource information received from the management server 16 to the corresponding relay node 30 by using PDCCH, for example.
[000145] As a result of this, the relay nodes 30 belonging to the different base stations 10 can exchange information directly by using the resource block allocated by the management server 16. By virtue of the direct exchange of information enabling delay time reduction , if compared to the exchange of information carried out by the base stations 10 through the backbone network 12, it is possible to achieve the operation to avoid interference quickly according to a change in the communication state. (First Mode Operation)
[000146] The configurations of the relay node 30, the management server 16 and the like according to the first embodiment of the present invention are described above in relation to figures 9 to 13. Next, the operation according to the first embodiment of the present invention invention is described in relation to figure 14. The embodiment is based on the following premises.
[000147] - The relay node 30 uses the forward link and terminates the step until the completion of the RRC connection in the same procedure as the user equipment 20, and the subcell ID, reference pattern allocation and the like are already determined.
[000148] - Base station 10 and relay node 30 belonging to it are in sync.
[000149] - Grouping information indicating the relay node 30 and the user equipment 20 that belongs to relay node 30 is pre-supplied from base station 10 (base station 10 determines the need for retransmission based on the report CQI or TA information and allocates resources for retransmission when necessary).- Ptx_DL >> Ptx_RL, Ptx_AL (Ptx: maximum transmission power)
[000150] - Measures against interference in the direct link, particularly the direct link of a use equipment (UE LTE) that does not consider the existence of the relay node 30, are considered an important issue.
[000151] Figure 14 is a sequence graph showing the operation according to the first embodiment of the present invention. In the example shown in Fig. 14, relay node 30A and base station 10A are connected, and relay node 30B and base station 10B are connected. In this case, base station 10A transmits management information indicating the state of the cell formed by base station 10A to management server 16 (S404). Also, base station 10B transmits management information indicating the state of the cell formed by base station 10B to management server 16 (S408).
[000152] Thereafter, the pairing unit 164 of the management server 16 pairs the two relay nodes 30 which are likely to cause interference with each other based on the management information received from each base station 10 (S412). Then, the resource allocation unit 166 of the management server 16 allocates a resource block to the two paired relay nodes 30 (the relay node 30A and the relay node 30B) to exchange information with each other (S420) .
[000153] Then, the management server 16 transmits the resource information indicating the resource block for exchanging information to the base station 10A to which the relay node 30A belongs and to the base station 10B to which the relay node 30B belongs ( S420, S424). Additionally, base station 10A transmits the resource information to relay node 30A and base station 10B transmits resource information to relay node 30B (S428, S432).
[000154] After that, the relay node 30A and the relay node 30B that belong to the different base stations 10 exchange information directly by using the resource block allocated by the management server 16 (S436). As a result, relay node 30A and relay node 30B can avoid interference between the subcell formed by relay node 30A and the subcell formed by relay node 30B based on the exchanged information. <3. Second Mode>
[000155] The first embodiment of the present invention is described in the foregoing. Next, a second embodiment of the present invention is described. The second modality of the present invention is different from the first modality, mainly, in that an entity that allocates a resource block to exchange information is not the management server 16. (Relay Node Configuration)
[000156] Figure 15 is a functional block diagram that shows a configuration of a relay node 30' according to the second mode. Referring to Fig. 15, relay node 30' includes a plurality of antennas 320a to 320n, an analog processing unit 324, an AD/DA conversion unit 328, and a digital processing unit 330. The digital processing unit 330 includes a synchronous unit 332, a decoder 334, a buffer 338, an encoder 340, a control unit 342, a relay node detection unit 344 and an interference determination unit 346.
[000157] The synchronous unit 332, the decoder 334, the encoder 340 and the like, together with the plurality of antennas 320a to 320n, the analog processing unit 324 and the AD / DA conversion unit 328, function as a receiving unit , a transmission unit and a relay unit for communicating with the base station 10 or with the user equipment 20. The elements that function as a receiving unit, a transmission unit and a relay unit are substantially the same as those of the first. modality and thus detailed explanation of these is omitted.
[000158] In the following, the control unit 342, the detection unit of the relay node 344 and the interference determination unit 346 are described in each case where the relay node 30' can receive a signal from a adjacent base station and wherein it is unable to receive a signal from an adjacent base station. (When Signal is Received from Adjacent Base Station)
[000159] The detection unit of relay node 344 acquires control information, such as scheduling information, from the PDCCH or PBCH that is received from an adjacent base station (a base station adjacent to the base station 10 to which relay node 30' belongs) and detects the existence of an adjacent relay node belonging to the adjacent base station 10. Note that when the adjacent base station operates in MBSFN with the adjacent relay node, the detection unit does relay node 344 can acquire control information from the R-PDCCH that is received from the adjacent base station.
[000160] The interference determination unit 346 determines whether the adjacent relay node detected by the relay node detection unit 344 is likely to interfere with the relay node 30'. For example, the interference determination unit 346 can refer to the scheduling information of the adjacent relay node and determine that interference is likely when there is a resource block that overlaps in temporal frequency with the scheduling information of the relay node 30' .
[000161] The control unit 342 performs connection processing in such a way that the relay node 30' is connected to belong to the adjacent relay node which is determined by the interference determination unit 346 as likely to cause interference, by the access connection. For example, the control unit 342 can explicitly notify the ID of the relay node adjacent to the adjacent base station when doing UL sync and connection register with the adjacent base station.
[000162] Additionally, the adjacent base station may determine that retransmission by an adjacent relay node is necessary when the CQI of the relay node 30' is low. Thus, the control unit 342 can transmit a CQI report that indicates a low CQI or a high QoS request to the adjacent base station.
[000163] As a result of this, the relay node 30' is connected to belong to the adjacent relay node as a pseudo-user equipment 20, and a resource block for the relay node 30' and the adjacent relay node to communicate over the access link is allocated by the adjacent base station. Thereby, the relay node 30' can transmit the information held by the relay node 30' to the adjacent base station by using the UL of the access link.
[000164] The relay node 30' adds an identifier indicating that it is information from a relay node that belongs to a different base station in the information to be transmitted. When the identifier is added and a resource block can be reserved for the DL of the access link, the adjacent relay node can transmit information held by the adjacent relay node to the relay node 30' by using the DL of the access link.
[000165] Note that relay node 30' may be in multilink connection with an adjacent relay node. Specifically, relay node 30' can be connected with an adjacent relay node while still maintaining the connection to base station 10. Additionally, relay node 30' can be connected with an adjacent base station, still maintaining the connection with the base station 10. Furthermore, when an adjacent relay node is allowed to connect to the relay node 30', the control unit 342 can directly perform UL synchronization and connection processing with the adjacent relay node. Additionally, although the case where the relay node 30' is connected with an adjacent relay node by using the access link is above described, connection can be made by using the relay link, not the access link. (When Signal is Not Receiving from Adjacent Base Station)
[000166] Relay node 30' performs receive processing intermittently based on control by control unit 342. Relay node detection unit 344 detects the existence of an adjacent relay node based on the condition of a signal being received from an adjacent relay node by intermittent receive processing.
[000167] The interference determination unit 346 determines whether the adjacent relay node detected by the relay node detection unit 344 is likely to interfere with the relay node 30'. For example, the interference determination unit 346 can query the scheduling information contained in the PDCCH received from the adjacent relay node and determine that it is likely to interfere when there is a resource block that overlaps in temporal frequency with the information. 30' relay node schedule.
[000168] The control unit 342 performs link processing in such a way that the relay node 30' is wired to belong to the adjacent relay node which is determined by the interference determination unit 346 as likely to interfere by the access link. . For example, the control unit 342 may perform connection processing with the adjacent base station through the base station 10 or it may perform connection processing directly with the adjacent relay node.
[000169] As a result of this, the relay node 30' is connected to belong to the adjacent relay node as a pseudo-user equipment 20, and a resource block to the relay node 30' and the adjacent relay node for communication by the access link is allocated by the adjacent base station. Thereby, the relay node 30' can transmit the information held by the relay node 30' to the adjacent base station by using the UL of the access link.
[000170] The relay node 30' adds an identifier indicating that it is information from a relay node that belongs to a different base station than the information to be transmitted. When the identifier is added and a resource block can be reserved for the DL of the access link, the adjacent relay node can transmit information held by the adjacent relay node to the relay node 30' by using the DL of the access link.
[000171] Note that relay node 30' may be in multilink connection with an adjacent relay node. Specifically, relay node 30' can be connected to an adjacent relay node while still maintaining the connection to base station 10. Additionally, relay node 30' can be connected to an adjacent base station, still maintaining the connection to the base station 10. Although the case where the relay node 30' is connected with an adjacent relay node by using the access link is above described, connection can be made by using the relay link, not the access link. (Second Mode Operation)
[000172] The configuration according to the second embodiment of the present invention is described above. Next, the operation according to the second embodiment of the present invention is described.
[000173] Fig. 16 is a sequence graph showing an example of connection processing in the case where the relay node 30'A is located at the location where it can communicate with the base station 10B, which is a base station adjacent. In the example shown in Fig. 16, relay node 30'A and base station 10A are connected, and relay node 30'B and base station 10B are connected. When relay node 30'A determines that it is likely to interfere with relay node 30'B, relay node 30'A makes a request to connect relay node 30'B to base station 10B (S504 ).
[000174] The base station 10B transmits an acknowledgment of the connection request to the relay node 30'A as a response to the request (S508), and transmits a connection command for connection with the relay node 30'A to the relay node 30'B (S512).
[000175] Then, relay node 30'B transmits a command acknowledgment to base station 10B as a response to connect command (S516), performs connection processing with relay node 30'A, and then grants a connection completion notification to relay node 30'A (S520). Then, relay node 30'A transmits a connection completion confirmation to relay node 30'B as a response to connection completion notification (S524). Thereafter, relay node 30'B delivers a report that it is connected at relay node 30'A to management server 16 via base station 10B (S528, S532).
[000176] By the above process, the relay node 30'A and the relay node 30'B are connected by the access link, and they can exchange information by using the resource block allocated on the access link (S536). Note that communication in S520 and S524 can be performed directly between base station 10B and relay node 30'A, as shown in S520' and S524', in an alternative example of Figure 17. In this case, the relay node 30'B relay can deliver connection completion notification to base station 10B, also at S516, and does not perform communication (connection report) at S528 shown in figure 16.
[000177] Fig. 18 is a sequence graph showing an example of the connection processing in the case where the relay node 30'a is located outside the communication range of the base station 10B, which is an adjacent base station. As shown in Figure 18, when relay node 30'A determines that it is likely to interfere with relay node 30'B, relay node 30'A makes a request for registration necessary to connect to relay node 30'B to base station 10B via base station 10A and backbone network 12 (S544, S548).
[000178] Then, base station 10B registers as requested and delivers a connection completion notification indicating that registration is complete to relay node 30'A through backbone network 12 and base station 10A (S552, S556). Thereafter, the relay node 30'A transmits a connection request to the relay node 30'B (S560), and the relay node 30'B transmits an acknowledgment of the connection request to the relay node 30'A as a response to the connection request (S564).
[000179] Then, after relay node 30'B receives a connection completion notification from relay node 30'A (S568), relay node 30'B delivers a report that it is connected with relay node 30'A to management server 16 via base station 10B (S572, S576). By the above method, the relay node 30'A and the relay node 30'B are connected by the access link, and they can exchange information by using the resource block allocated on the access link (S580).
[000180] Fig. 19 is a sequence graph showing an example of the connection processing in the case where the relay node 30'A is located outside the communication range of the base station 10B, which is an adjacent base station, and relay node 30'B is allowed to connect to relay node 30'A. As shown in Figure 19, when relay node 30'A determines that it is likely to interfere with relay node 30'B, relay node 30'A makes a request to connect directly to relay node 30'B (S604). Then, the relay node 30'B performs necessary processing for connection and transmits an acknowledgment of the connection request to the relay node 30'A as a response to the connection request (S608).
[000181] Then, after relay node 30'B receives a connection completion notification from relay node 30'A (S612), relay node 30'B delivers a report that it is connected with relay node 30'A to management server 16 via base station 10B (S616, S620). By the above method, the relay node 30'A and the relay node 30'B are connected by the access link, and they can exchange information by using the resource block allocated on the access link (S624). <4. Other Applications of the Invention>
[000182] As described above, a plurality of relay nodes 30 and 30' exchange information by using data communication resources. However, the above-described relay nodes 30 and 30' are just an example of small to medium sized base stations in the heterogeneous network described below. Therefore, it is also within the scope of the present invention for a plurality of small to medium sized base stations to exchange information by radio using the data communication facilities.
[000183] A heterogeneous network is a network in which a plurality of small to medium sized base stations coexist in a macrocell by overlay transmission or spectrum sharing. The small to medium sized base station can be an RRH cellular base station (Remote Radio Head), a fast zone base station (picocell / microcellular eNB), a femtocellular base station (home eNB), a relay node (station transmission base) or the like. The heterogeneous network architecture is specifically described below.
[000184] Figure 20 is an explanatory view that shows an example of heterogeneous network architecture. Referring to Figure 20, the heterogeneous network includes a macrocellular base station 10 (which is synonymous with a base station 10), a relay node 30, a fast zone base station 31, a femtocellular base station 32, RRH cellular base stations 33 and management servers 16A and 16B.
[000185] The management servers 16A and 16B have functions for the macrocellular base station 10 and the small to medium sized base stations to operate in cooperation with each other. For example, as described in <2. First Mode (Management Server Configuration)>, the management server 16A receives information (position information, scheduling information, QoS information, etc.) relating to macrocellular base station 10 or user equipment 20 belonging to base station small to medium sized, pair small to medium sized base stations that are likely to interfere with each other, or allocate a resource block for information exchange. Note that the functions of the management server 16 can be incorporated into the macrocellular base station 10 or any of the small to medium sized base stations, and the macrocellular base station 10 and the small to medium sized base stations in which the functions are built-in can perform central control. Or the functions of the management server 16 may be incorporated into a plurality of parts of the macrocellular base station 10 or the small to medium sized base stations, and the macrocellular base station 10 or the small to medium sized base stations in which the functions are embedded can perform autonomous control.
[000186] The macrocellular base station 10 manages the small to medium sized base stations and the user equipment 20 in the macrocell. The configuration of macrocellular base station 10 is described above in <2. First Mode (Base Station Setup)>.
[000187] The fast zone base station 31 has the maximum transmission power lower than the macrocellular base station 10 and communicates with the macrocellular base station 10 using an interface, such as X2 or S1, of a central network. Note that fast zone base station 31 creates OSG (Open Subscriber Group), which is accessible from any user equipment 20.
[000188] The femtocellular base station 32 has the maximum transmission power lower than the macrocellular base station 10 and communicates with the macrocellular base station 10 using a packet exchange network, such as ADSL. Alternatively, femtocellular base station 32 can communicate with macrocellular base station 10 over a radio link. Note that femtocellular base station 32 creates CSG (Closed Subscriber Group), which is only accessible from limited user equipment 20.
[000189] The cellular base station RRH 33 is connected with the macrocellular base station 10 by an optical fiber. Thus, macrocellular base station 10 transmits signals to cellular base stations RRH 33A and 33B installed in geographically different locations through optical fiber and allows cellular base stations RRH 33A and 33B to transmit signals by radio. For example, only cellular base stations RRH 33 close to the position of user equipment 20 can be used. Note that functions related to a control system are incorporated in the macrocellular base station 10, and the optimal transmission mode is selected according to the distribution of the user equipment 20.
[000190] Figure 21 shows the overview of the respective small to medium sized base stations described above. The example configuration of small to medium sized base stations 40, such as fast zone base station 31 and femtocellular base station 32, is illustrated in Fig. 22. As shown in Fig. 22, small to medium sized base stations medium 40, such as fast zone base station 31 and femtocellular base station 32, include a backbone communication unit 450 for communicating with the wired side of the network. On the other hand, other configurations of the small to medium sized base stations 40 are considered to be substantially the same as those of the relay node 30' explained in relation to Fig. 15 (or of the relay node 30 explained in relation to Fig. 11).
[000191] Small to medium size 40 base stations, as stated, can avoid interference with other communications by exchanging information using data communication resources. In the following, information exchange between small to medium sized base stations 40 will be described after explaining an interference model and an interference avoidance control in a heterogeneous network. (Heterogeneous Network Interference Model)
[000192] Figure 23 is an explanatory view that shows the interference model in a heterogeneous network. In Figure 23 and Figures 24 to 26 described below, relay node 30, fast zone base station 31, femtocellular base station 32 and the like are not particularly distinguished from each other, and they are shown simply as base stations from small to medium size 40.
[000193] In relation to figure 23, the occurrence of the following interferences is considered in the heterogeneous network.
[000194] (1) Interference between a broadcast signal coming from a small to medium size base station 40A and a broadcast signal coming from the macrocellular base station 10 that occurs in the user equipment 20A-2.
[000195] (2) Interference between a broadcast signal coming from the user equipment 20B-2 and a broadcast signal coming from the macrocellular base station 10 that occurs at a small to medium sized base station 40B.
[000196] (3) Interference between a broadcast signal coming from a small to medium sized base station 40C and a broadcast signal coming from the macrocellular base station 10 that occurs at a small to medium sized base station 40D.
[000197] (4) Interference between a broadcast signal coming from a small to medium sized base station 40 and a broadcast signal coming from the 20F-2 user equipment that occurs in the 20E-2 user equipment. Interference in the Heterogeneous Network)
[000198] Although several types of interferences occur in the heterogeneous network, as exposed, the interferences can be resolved by a transfer, transmission power control or beamforming. An example of the interference avoidance control is specifically described below.
[000199] Figure 24 is an explanatory view that shows an example of transfer interference avoidance. In the left part of Fig. 24, a broadcast signal from the small to medium size base station 40A and a broadcast signal from the macrocellular base station 10 interfere with the user equipment 20A-2. In this case, the interference can be resolved by transferring the user equipment 20A-2 from the 40A small to medium size base station to a 40G small to medium size base station with different transmission timing than the macrocellular base station 10.
[000200] Additionally, in the left part of Fig. 24, a transmit signal from the small to medium sized base station 40E and a transmit signal from the 20F-2 user equipment interfere with the 20E-2 user equipment. In this case, the interference can be resolved by transferring the 20E-2 user equipment from the 40E small to medium size base station to the 40F small to medium size base station. Note that the small to medium sized base station 40E and the small to medium sized base station 40F can exchange the necessary information at the time of transfer by using a resource block allocated by the management server 16.
[000201] Figure 25 is an explanatory view that shows an example of interference avoidance by beamforming. In the left part of Fig. 25, a broadcast signal from the small to medium size base station 40A and a broadcast signal from the macrocellular base station 10 interfere with the user equipment 20A-2. In this case, the interference can be resolved by directing the receive directivity of the 20A-2 user equipment in the direction in which the 40A small to medium size base station is placed.
[000202] Additionally, in the left part of Fig. 25, a transmit signal coming from the small to medium sized base station 40E and a transmit signal coming from the user equipment 20F-2 interfere with the user equipment 20E-2. In this case, the interference can be resolved by directing the transmit directivity of the 20F-2 user equipment to the direction in which the small to medium sized base station 40F is placed by virtue of the transmit signal coming from the 20F user equipment -2, thereby not reaching the 20E-2 user equipment. Note that the 40F small to medium size base station receives the interference state due to the 20F-2 user equipment, the 20E-2 user equipment position information or the like from the 40E small to medium size base station using a resource block allocated by the management server 16, for example, and performs interference avoidance control based on the information received.
[000203] Figure 26 is an explanatory view that shows an example of interference avoidance by controlling the transmission power. In the left part of Fig. 26, a broadcast signal from the small to medium size base station 40A and a broadcast signal from the macrocellular base station 10 interfere with the user equipment 20A-2. In this case, if the transmission power of the small to medium sized base station 40A decreases, the user equipment 20A-2 is excluded from the radio range of the small to medium sized base station 40A and thus the connection between the equipment 20A-2 user base station and 40A small to medium size base station is disabled. In this way, user equipment 20A-2 searches for a new connection and makes a connection at macrocellular base station 10, for example. Therefore, the interference can be resolved by decreasing the transmission power of the small to medium size 40A base station.
[000204] Additionally, in the left part of Fig. 26, a transmit signal coming from the small to medium sized base station 40E and a transmit signal coming from the user equipment 20F-2 interfere with the user equipment 20E-2. In this case, if the transmission power of the base station of small to medium size 40F decreases, the user equipment 20F-2 is excluded from the radio range of the base station of small to medium size 40F and thus the connection between the equipment user 20F-2 and the 40F small to medium size base station is disabled. In this way, user equipment 20F-2 searches for a new connection and makes a connection at macrocellular base station 10, for example. Therefore, the interference can be resolved by decreasing the transmission power of the small to medium size 40F base station. Note that the 40F small to medium sized base station receives the interference state due to 20F-2 user equipment or the like from the 40E small to medium sized base station using a resource block allocated by the management server 16, per example, and performs interference avoidance control based on the information received. (Information Exchange Method)
[000205] The small to medium sized base station 40 can exchange information directly by radio with a nearby small to medium sized base station 40 in accordance with any of the method described in <2. First Modality> and the method described in <3. Second Mode>. For example, as shown in Figure 27, small to medium sized base stations 40E and 40F located in the same macrocell can exchange information directly with each other.
[000206] Specifically, as described in <2. First Modality>, the small to medium sized base station 40 can exchange information with the nearby small to medium sized base station 40 paired by the management server 16 by using a resource block that is allocated by the management server 16.
[000207] Additionally, as described in <3. Second Mode>, the small to medium sized base station 40 can be connected with the nearby small to medium sized base station 40 as the user equipment and exchange information by using a resource block that is allocated from the station nearby small to medium size base 40 as a communication resource for the access link. This is described below by way of illustration in relation to figure 28.
[000208] Fig. 28 is an explanatory view showing a sequence for exchanging information between a plurality of small to medium sized base stations 40. Fig. 28 shows an example in which small to medium sized base stations 40E and 40F are under the management of macrocellular base station 10.
[000209] First, when the 40E small to medium sized base station determines that interference is likely to occur between the 40E small to medium sized base station controlled communication and the 40F small to medium sized base station controlled communication, the small to medium size base station 40E makes a connection request from the small to medium size base station 40F to macrocellular base station 10 (S704). Although each small to medium sized base station 40 has an interface to make direct communication with the management server 16 in some cases, because it is under the management of the macrocellular base station 10, it carries out communication to exchange information with the station. macrocellular base 10.
[000210] It should be noted that an interface between the macrocellular base station 10 and the small to medium sized base station 40 differs depending on the type of the small to medium sized base station 40. For example, when the sized base station small to medium 40 is the fast zone base station 31, the small to medium size base station 40 and the macrocellular base station 10 perform communication by using the X2 interface. Additionally, when the small to medium sized base station 40 is the femtocellular base station 32, the small to medium sized base station 40 and the macrocellular base station 10 perform communication by performing tunneling of the X2 interface in the packet exchange network.
[000211] The macrocellular base station 10 transmits an acknowledgment of the connection request to the small to medium size base station 40E as a response to the request of the small to medium size base station 40E (S708) and transmits a connection command for connection to the small to medium size base station 40E to the small to medium size base station 40F (S712). Then, macrocellular base station 10 receives a command acknowledgment from the small to medium sized base station 40F as a response to the connection command (S716), performs scheduling a connection parameter for connection between the small sized base station to medium 40E and the small to medium sized base station 40F and then transmits the connection parameter to the small to medium sized base station 40E (S724).
[000212] Thereafter, the small to medium size base station 40E and the small to medium size base station 40F perform connection processing according to the connection parameter transmitted from the macrocellular base station 10 (S728). In the process of link processing, adjustment of transmit/receive timing or transmit power can be performed between the small to medium size base station 40E and the small to medium size base station 40F. Then, the small to medium sized base station 40F grants a connection completion notification to the small to medium sized base station 40E (S732), and the small to medium sized base station 40E transmits a connection completion confirmation to the station. small to medium size base 40F as a response to the connection completion notification (S736).
[000213] Then, the small to medium sized base station 40F delivers a report that it is connected at the small to medium sized base station 40E to the management server 16 through the macrocellular base station 10 (S740, S744). By the above process, the small to medium sized base station 40E and the small to medium sized base station 40F can reserve the link enabling radio link and exchange information directly by using the resource block allocated in the radio link (S748) . <Summary>
[000214] As described above, according to the first embodiment of the present invention, small to medium sized base stations, such as relay nodes 30, can exchange information directly with each other by using a resource block allocated by the management server 16. Additionally, in accordance with the second embodiment of the present invention, a small to medium sized base station, such as relay node 30', performs connection processing to belong to an adjacent small to medium sized base station. medium and therefore can exchange information directly with the adjacent small to medium sized base station by using the access link. Because direct information exchange enables delay time reduction compared to information exchange performed by base stations 10 through backbone network 12, it is possible to achieve interference avoidance operation quickly according to a change in communication status.
[000215] Although preferred embodiments of the present invention are described in detail above in relation to the accompanying drawings, the present invention is not limited thereto. Skilled in the art understand that various modifications, combinations, sub-combinations and alterations may occur, depending on design requirements and other factors, to the extent that they fall within the scope of the appended claims or their equivalents.
[000216] For example, it is not always necessary to perform the respective processing steps of the communication system 1 of this specification in chronological order according to the sequence shown in the sequence graphics. For example, the respective processing steps of the communication system 1 can be carried out in a sequence different from the sequence shown in the sequence graphs or they can be carried out in parallel.
[000217] Furthermore, it is possible to create a computer program that makes hardware, such as a CPU, a ROM and a RAM, incorporated in the relay node 30, the management server 16 and the like to work equally with the respective elements of relay node 30, management server 16, and the like described above. Additionally, a memory media that stores a computer program like this can be provided.REFERENCE SIGNALS LIST10 Base station 16 Management server20 User equipment30, 30' Relay node124, 224, 324 Analog processing unit128, 228, 328 AD / DA conversion unit130, 230, 330 Digital processing unit134, 234, 334 Decoder140, 240, 340 Encoder142, 242, 342 Control unit164 Pairing unit166 Resource allocation unit232, 332 Synchronous unit338 Temporary storage

权利要求:
Claims (14)
[0001]
1. Relay node (30A) in a mobile communication network (1) to receive a radio signal from a first base station (10A) and to forward the signal to a first mobile station (20A), the node of relay (30A) characterized in that it comprises: a control unit (342) configured to manage a first information corresponding to a link between the relay node (30A) and the first mobile station (20A); a transmitter configured to transmit the first information directly to another relay node (30B) in the mobile communication network (1), associated with a second base station (10B); a receiver configured to receive, from the other relay node (30B), second information corresponding to a connection between the other relay node (30B) and the second mobile station (20B); and wherein the control unit (342) is configured to control resources used to communicate with the first mobile station (20A) based on the first information and second information, wherein the receiver is configured to receive resource allocation information from the first base station (10A), indicating communication resources assigned to the relay node (30A) to communicate directly with the other relay node (30B), and wherein the transmitter is configured to directly transmit the first information to the other relay node ( 30B) in the mobile communication network (1) based on the resource allocation information received from the first base station (10A).
[0002]
2. Relay node (30A) according to claim 1, characterized in that: the control unit (342) is configured to determine whether the link between the other relay node (30B) and the second mobile station (20B) interferes with the connection between the relay node (30A) and the first mobile station (20A) based on the first information and the second information.
[0003]
3. Relay node (30A) according to claim 2, characterized in that: the control unit (342) is configured to modify resources used to communicate with the first mobile station (20A) based on the determination that the connection between the other relay node (30B) and the second mobile station (20B) interferes with the connection between the relay node (30A) and the first mobile station (20A).
[0004]
4. Relay node (30A), according to any one of claims 1 to 3, characterized in that it further comprises: a relay node detection unit (30A) configured to detect the existence of the other relay node ( 30B) by detecting a signal transmitted from the other relay node (30B).
[0005]
5. Relay node (30A) according to claim 4, characterized in that it further comprises: an interference determination unit configured to determine whether the signal detected by the detection unit of the relay node (30A) interferes with the connection between the relay node (30A) and the first mobile station (20A).
[0006]
6. Relay node (30A), according to any one of claims 4 or 5, characterized in that: the detection unit of the relay node (30A) is configured to detect the existence of the other relay node (30B ) based on signals transmitted from the second base station (10B) to which the other relay node (30B) is connected, and the control unit (342) is configured to request a direct communication link with the other relay node. relay (30B) to the second base station (10B).
[0007]
7. Relay node (30A), according to any one of claims 4 to 6, characterized in that: the detection unit of the relay node (30A) is configured to detect the existence of the other relay node (30B ) based on the signals transmitted from the other relay node (30B), and the control unit (342) is configured to request a direct communication link with the other relay node (30B) from the base station (10A) to which the relay node (30A) is connected.
[0008]
8. Relay node (30A), according to any one of claims 4 to 6, characterized in that: the detection unit of the relay node (30A) is configured to detect the existence of the other relay node (30B ) based on signals transmitted from the other relay node (30B), and wherein the control unit (342) is configured to request a direct communication link with the other relay node (30B) by transmitting a request for connect directly to the other relay node (30B).
[0009]
9. Relay node (30A), according to any one of claims 1 to 8, characterized in that the first information corresponding to the connection between the relay node (30A) and the first mobile station (20A) includes information of identification corresponding to the first mobile station (20A).
[0010]
10. Relay node (30A) according to any one of claims 1 to 9, characterized in that the first information corresponding to the connection between the relay node (30A) and the first mobile station (20A) includes an indicator of a permissible interference level corresponding to the connection between the relay node (30A) and the first mobile station (20A).
[0011]
11. Relay node (30A), according to any one of claims 1 to 10, characterized in that the first information corresponding to the connection between the relay node (30A) and the first mobile station (20A) includes a channel quality indicator (CQI) corresponding to the connection between the relay node (30A) and the mobile station (20A).
[0012]
12. Relay node (30A) according to any one of claims 1 to 11, characterized in that the first information corresponding to the connection between the relay node (30A) and the first mobile station (20A) includes information of quality of service (QoS) corresponding to a quality of the connection required between the relay node (30A) and the first mobile station (20A).
[0013]
13. Non-transient computer readable medium, characterized in that it includes computer readable instructions which, when executed by a relay node (30A) in a communication network (1), cause the relay node (30A) performs a method for receiving a radio signal from a first base station (10A) and for routing the signal to a first mobile station (20A), the method comprising: managing the first information corresponding to a connection between the relay node (30A) and the mobile station (20A); directly transmitting the first information to another relay node (30B) in the mobile communication network (1), associated with a second base station (10B); receiving, from the other relay node (30B), second information corresponding to a connection between the other relay node (30B) and a second mobile station (20B); and controlling resources used to communicate with the first mobile station (20A) based on the first information and the second information; wherein the relay node (30A) receives resource allocation information from the first base station (10A), indicating resources assigned to the relay node (30A) to communicate directly with the other relay node (30B), and wherein the relay node (30A) directly transmits the first information to the other relay node (30B) in the mobile communication network. (1) based on resource allocation information received from the first base station (10A).
[0014]
14. Method, performed by a relay node (30A) in a communication network (1) that receives a radio signal from a first base station (10A) and forwards the signal to a first mobile station (20A), characterized in that the method comprises: managing, in a control unit (342) of the relay node (30A), first information corresponding to a link between the relay node (30A) and the first mobile station (20A); directly transmit, using a transmitter of the relay node (30A), the first information to another relay node (30B) in the mobile communication network (1), associated with a second base station (10B); from the relay node (30A), from the other relay node (30B), second information corresponding to a link between the other relay node (30B) and the second mobile station (20B); and controlling, with the control unit (342) of the relay node (30A), resources used to communicate with the first mobile station (20A) on the basis of the first information and the second information; wherein the receiver is configured to receive information from resource allocation from the first base station (10A), indicating communication resources assigned to the relay node (30A) to communicate directly with the other relay node (30B), and wherein the transmitter is configured to directly transmit the first information to the other relay node (30B) in the mobile communication network (1) based on the resource allocation information received from the first base station (10A).

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---

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

CN101069378B|2004-08-31|2014-07-23|艾利森电话股份有限公司|Data unit sender and data unit relay device|

---

CN101064914B|2006-04-29|2010-11-10|上海贝尔阿尔卡特股份有限公司|Method and apparatus for performing combined relay in wireless communication network|

---

CN101064915B|2006-04-29|2016-10-05|上海贝尔股份有限公司|Within a wireless communication network for the method and device of many relay stations combined relaying|

---

US20070291663A1|2006-06-19|2007-12-20|Nokia Corporation|Method and apparatus for scale-free topology generation in relay based wireless networks|

---

JP4583430B2|2007-11-08|2010-11-17|日本電信電話株式会社|Wireless communication system|

---

JP5045506B2|2008-03-12|2012-10-10|富士通株式会社|Communication method and wireless communication system|

---

JP5039639B2|2008-06-09|2012-10-03|株式会社日立製作所|Communication device having path protection function and network system using the communication device|

---

US8289894B2|2008-09-15|2012-10-16|Sharp Laboratories Of America, Inc.|Systems and methods for inter relay interference coordination|

---

CN101938775B|2009-06-29|2017-07-18|宏达国际电子股份有限公司|Handle mobile device mobility method and its related communication device|

---

JP2011091783A|2009-09-25|2011-05-06|Sony Corp|Communication system, base station, relay node, and user equipment|KR101650749B1|2009-08-18|2016-08-24|삼성전자주식회사|Method and apparatus for allocation and indication of control channel in backhaul subframe for relay|

---

US20110228700A1|2010-03-16|2011-09-22|Telefonaktiebolaget Lm Ericsson |Subframe Allocation for In-Band Relay Nodes|

---

JP5814041B2|2011-08-12|2015-11-17|株式会社Ｎｔｔドコモ|Radio communication system, radio base station apparatus, user terminal, and radio communication method|

---

US9143274B2|2011-10-31|2015-09-22|Massachusetts Institute Of Technology|Traffic backfilling via network coding in a multi-packet reception network|

---

EP2807878A4|2012-01-29|2015-07-15|Alcatel Lucent|A high interference indicator for time division duplex wireless communication systems|

---

US20160050621A1|2013-03-22|2016-02-18|Sharp Kabushiki Kaisha|Terminal device, base station device, and control device|

---

WO2015073937A1|2013-11-17|2015-05-21|Ping Liang|Massive mimo multi-user beamforming and single channel full duplex for wireless networks|

---

WO2015095844A1|2013-12-20|2015-06-25|Ping Liang|Adaptive precoding in a mimo wireless communication system|

---

KR102317372B1|2013-12-20|2021-10-25|핑 리앙|Method for acquiring channel state information in fdd mimo wireless networks|

---

US9571587B1|2014-03-10|2017-02-14|Sprint Spectrum L.P.|Coordinating communication with a wireless device|

---

DE102014221956A1|2014-10-28|2016-05-12|Bayerische Motoren Werke Aktiengesellschaft|Apparatus, vehicle, method and computer program for a relay transceiver and a network component|

---

WO2017026443A1|2015-08-11|2017-02-16|京セラ株式会社|Wireless terminal and base station|

---

KR20170138877A|2016-06-08|2017-12-18|삼성전자주식회사|Relay communication method of a user equipment and the user equipment|

---

US10187841B1|2017-09-29|2019-01-22|Wipro Limited|Method and system for switching data-paths in heterogeneous wireless communication networks|

---

US10749592B1|2017-10-24|2020-08-18|Sprint Spectrum L.P.|Scheduling resources for relay nodes in a wireless network|

---

US10892883B2|2018-03-27|2021-01-12|Qualcomm Incorporated|Resource coordination for half duplex communications|

法律状态:
2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-01-21| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2020-03-17| B15K| Others concerning applications: alteration of classification|Free format text: AS CLASSIFICACOES ANTERIORES ERAM: H04W 16/26 , H04B 7/15 , H04W 92/16 Ipc: H04B 7/155 (2006.01), H04B 7/26 (2006.01), H04W 72 |

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2021-05-04| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-08-24| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 29/07/2010, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |

优先权:

---

申请号 | 申请日 | 专利标题

---

JP2009220481|2009-09-25|

---

JP2009-220481|2009-09-25|

---

JP2010040227A|JP2011091786A|2009-09-25|2010-02-25|Communication system, relay node, user equipment, and base station|

---

JP2010-040227|2010-02-25|

---

PCT/JP2010/004817|WO2011036839A1|2009-09-25|2010-07-29|Communication system, relay node, user equipment and base station|

---