JP4654253B2 - Radio base station apparatus, radio terminal apparatus, and radio communication method - Google Patents

Description

  The present case relates to a radio base station apparatus, a radio terminal apparatus, and a radio communication method that perform radio communication.

  LTE (Long Term Evolution), which is being standardized in a 3rd generation partnership project (3GPP: 3rd Generation Partnership Project), is a mobile communication system capable of 100 Mbps data transmission in the downlink.

  In a radio communication system in LTE, an orthogonal frequency division multiplexing (OFDM) scheme is used as a communication scheme between a radio base station and a plurality of radio terminal apparatuses in its management area. . A frame exchanged between a radio base station and a radio terminal device is mainly divided into a data channel (shared channel: SCH: Shared CH) and a control channel (CCH: Control CH) (for example, the following non-patent document) 1).

  Regarding communication in the download direction from the radio base station to the radio terminal device, the radio base station, for example, when the frame band (system band) is 20 MHz, divides the shared channel of the frame into resource blocks of 15 kHz, Allocation information (mapping information) indicating which transmission data is allocated to each resource block is stored in the control channel. Each allocation information of each transmission data is code-multiplexed and stored in the control channel.

  The wireless terminal device that has received this frame from the wireless base station acquires assignment information from the control channel of the frame, and determines whether transmission data addressed to itself is assigned to the frame. When the transmission data addressed to itself is assigned to the frame, the wireless terminal device acquires the transmission data addressed to itself from the data channel of the frame based on the allocation information.

“Downlink transport channels and control information”, [online], 3GPP, [December 26, 2007 search], Internet <URL: http: // www. 3 gpp. org / ftp / Specs / archive / 36_series / 36.212 / 36212-810. zip>, chapter 5.3

  However, in the above-described prior art, there is a limit on the capacity of information that can be stored in the control channel of a frame. On the other hand, as the number of transmission data allocated to one frame increases, the capacity of allocation information stored in the control channel increases. For this reason, even if there is a space in the data channel, there is a problem that if the capacity of the allocation information exceeds the capacity limit of the control channel, no more transmission data can be allocated to the data channel.

  For this reason, it is necessary to allocate transmission data in a range that does not exceed the capacity limit of the control channel, and there is a space in the capacity of the data channel, and radio resources cannot be used efficiently. In particular, in a situation where the number of transmission data allocated to one frame is large and the capacity of each transmission data is small, the capacity of the allocation information exceeds the capacity limit of the control channel even though the data channel capacity is free. There are many cases. Further, the control channel of the frame in LTE is determined at the first and second symbols of the frame, and the capacity is severely limited.

  The disclosed radio base station apparatus, radio terminal apparatus, and radio communication method are intended to solve the above-described problems and to efficiently use radio resources.

  In order to solve the above-described problems and achieve the object, this radio base station apparatus sequentially transmits frames to which a plurality of radio terminal apparatuses are assigned transmission data to the radio terminal apparatuses. Allocation means for allocating each transmission data to a data channel of a target frame, and among the allocation information of each transmission data by the allocation means, the allocation information within the capacity limit of the control channel of the target frame is controlled. First transmission means for storing in a channel, second storage means for storing allocation information exceeding the capacity limit among the allocation information in a control channel of a frame different from the target frame, and the transmission data A transmission unit configured to transmit the allocated frame storing the allocation information to the plurality of wireless terminal devices. To.

  According to the above configuration, the allocation information that exceeds the capacity limit of the control channel among the allocation information of each transmission information allocated to the target frame is stored in the control channel of the frame different from the target frame, so that the data channel If there is an available capacity, transmission data can be allocated exceeding the capacity limit of the control channel.

  As described above, according to the disclosed radio base station apparatus, radio terminal apparatus, and radio communication method, there is an effect that radio resources can be efficiently used.

  Exemplary embodiments of a wireless base station device, a wireless terminal device, and a wireless communication method will be described below in detail with reference to the accompanying drawings.

(Outline of the embodiment)
FIG. 1 is a diagram illustrating an outline of a radio base station apparatus according to an embodiment. As illustrated in FIG. 1, the radio base station apparatus 100 according to this embodiment assigns each frame to which the transmission data # 1 to # 10 to the radio terminal apparatuses UE # 1 to UE # 10 are assigned to the radio terminal apparatus UE. # 1 to UE # 10 are sequentially transmitted. The radio base station apparatus 100 includes a buffer 111, an allocation unit 112, a first storage unit 114, a second storage unit 115, and a transmission unit 116.

  A frame 120 and a frame 130 indicate frames that the radio base station apparatus 100 sequentially generates and transmits. The frame 120 includes a data channel 121 and a control channel 122. Similarly, the frame 130 includes a data channel 131 and a control channel 132. Here, it is assumed that the frame 130 is a frame generated next to the frame 120. In addition, frames are sequentially generated after the frame 130.

  The buffer 111 temporarily stores transmission data # 1 to # 10. The destinations of transmission data # 1 to # 10 are wireless terminal apparatuses UE # 1 to UE # 10, respectively. The allocation unit 112 sequentially reads the transmission data # 1 to # 10 held in the buffer 111. The allocation unit 112 allocates each transmission data read from the buffer 111 within the range of the data channel capacity to the data channel of the frame to be generated.

  Here, assignment section 112 assigns transmission data # 1 to # 3 to data channel 121 of frame 120. The assigning unit 112 assigns transmission data # 4 to # 10 to the data channel 131 of the frame 130. The allocation unit 112 outputs the frame 120 and the frame 130 to which each transmission data is allocated to the storage unit 113.

  The storage unit 113 stores each allocation information of each transmission data allocated to the frame output from the allocation unit 112 in the control channel of the frame. The transmission data allocation information is information indicating to which part of the data channel the transmission data is allocated, and information on the destination of the transmission data (any one of the radio terminal apparatuses UE # 1 to UE # 10). Stored together. Each allocation information is code-multiplexed and stored in the control channel.

  Specifically, the storage unit 113 is divided into a first storage unit 114 and a second storage unit 115 as a functional configuration. The first storage unit 114 uses the allocation information within the capacity limit of the control channel of the target frame, out of the allocation information of each transmission data allocated to the target frame output from the allocation unit 112, for the target frame. Store in control channel.

  Here, it is assumed that the total capacity of the transmission data # 1 to # 3 allocated to the frame 120 is within the capacity limit of the control channel 122. In this case, the first storage unit 114 stores each piece of allocation information of the transmission data # 1 to # 3 in the control channel 122 of the frame 120, as indicated by a dotted line arrow. Further, it is assumed that the total capacity of the allocation information of transmission data # 4 to # 8 among the transmission data allocated to the frame 130 is within the capacity limit of the control channel 132.

  Further, it is assumed that the capacity limit of the control channel 132 is exceeded even if any capacity of the transmission data # 9 and # 10 is added to the total capacity of the allocation information of the transmission data # 4 to # 8. In this case, the first storage unit 114 stores the allocation information of the transmission data # 4 to # 8 in the control channel 132 of the frame 130, and stores the allocation information of the transmission data # 9 and # 10 in the control channel 132. do not do.

  The second storage unit 115 assigns allocation information exceeding the control channel capacity limit of the target frame, out of the allocation information of each transmission data allocated to the target frame output from the allocation unit 112, to the target frame. It is stored in a control channel in a different frame. Here, in the allocation information of the transmission data # 1 to # 3 allocated to the target frame 120, there is no allocation information exceeding the capacity limit of the control channel 122 of the frame 120.

  On the other hand, the allocation information of the transmission data # 9 and # 10 allocated to the target frame 130 is allocation information exceeding the capacity limit of the control channel 132 of the frame 130. Therefore, the second storage unit 115 stores the transmission data # 9 and # 10 in a control channel of a frame different from the frame 130 as indicated by the dotted arrow.

  For example, the second storage unit 115 stores the transmission data # 9 and # 10 in the control channel 122 of the frame 120 before the frame 130, as indicated by the downward curved dotted line arrow. Alternatively, the second storage unit 115 stores the transmission data # 9 and # 10 in the control channel of the frame generated next to the frame 130, as indicated by the upward curved dotted line arrow.

  In addition, when the second storage unit 115 stores the allocation information in the control channel of a frame different from the target frame, the second storage unit 115 identifies the flag information and a frame to be transmitted after the target frame and the different frame. The frame identification information to be stored is stored in the control channel of the frame to be transmitted first among the target frame and different frames.

  For example, when the second storage unit 115 stores the allocation information of the transmission data # 9 and # 10 allocated to the frame 130 in the control channel 122 of the frame 120, the second storage unit 115 transmits the information to that effect to the control channel 122 of the frame 120. To store. Alternatively, when the second storage unit 115 stores the allocation information of the transmission data # 9 and # 10 in the control channel of the frame next to the frame 130, the second storage unit 115 stores the information to that effect in the control channel 132 of the frame 130. .

  The storage unit 113 sequentially outputs each frame storing the allocation information to the transmission unit 116. The transmission unit 116 wirelessly transmits each frame sequentially output from the storage unit 113 to the radio terminal apparatuses UE # 1 to UE # 10. Each of radio | wireless terminal apparatus UE # 1-UE # 10 is a mobile terminal apparatus which exists in the management area (refer FIG. 2) of the radio | wireless base station apparatus 100. FIG.

  Each of radio terminal apparatuses UE # 1 to UE # 10 sequentially receives frames wirelessly transmitted from radio base station apparatus 100. Each of the radio terminal apparatuses UE # 1 to UE # 10 acquires transmission data addressed to the own apparatus allocated to the data channel of the received frame based on the allocation information stored in the control channel of the received frame.

  For example, when receiving the frame 120, the radio terminal apparatus UE # 1 acquires transmission data # 1 allocated to the data channel 121 based on the allocation information stored in the control channel 122 of the frame 120. Also, when receiving the frame 130, the radio terminal apparatus UE # 1 discards the frame 130 because assignment information destined for the radio terminal apparatus UE # 1 is not stored in the control channel 132 of the frame 130 .

  Each of the radio terminal apparatuses UE # 1 to UE # 10 extracts flag information and frame identification information stored in the control channel of the received frame. Each of the radio terminal apparatuses UE # 1 to UE # 10 acquires allocation information that exceeds the capacity limit described above and a target frame of the allocation information based on the extracted flag information and frame identification information. Each of the radio terminal apparatuses UE # 1 to UE # 10 acquires transmission data addressed to the own apparatus allocated to the data channel of the acquired target frame based on the acquired allocation information.

  For example, when the radio terminal apparatus UE # 9 receives the frame 120, information indicating that the allocation information of the transmission data # 9 allocated to the frame 130 is stored in the control channel 122 of the frame 120 is stored in the control channel 122. If so, the allocation information of transmission data # 9 is acquired from the control channel 122 and held. Then, when receiving the frame 130, the radio terminal apparatus UE # 9 acquires transmission data # 9 from the data channel 131 of the frame 130 based on the allocation information acquired and held from the control channel 122.

  Alternatively, when the radio terminal apparatus UE # 9 receives the frame 130, the information indicating that the allocation information of the transmission data # 9 allocated to the frame 130 is stored in the control channel of the next frame of the frame 130 is the control channel 132. If the received frame 130 is stored, the received frame 130 is held. Then, when the radio terminal apparatus UE # 9 receives the frame following the frame 130, the radio terminal apparatus UE # 9 receives the transmission data # 9 from the held frame 130 based on the allocation information stored in the control channel of the received frame. get.

(Embodiment 1)
FIG. 2 is a block diagram of a configuration of the wireless communication system according to the first embodiment. As illustrated in FIG. 2, the radio communication system 200 according to the first embodiment includes access gateways aGW1 and aGW2, radio base station apparatuses eNB1 to eNB3, and radio terminal apparatuses UE # 1 to # 10. It is configured. Each of the access gateways aGW1 and 2 has a function of accessing the backbone network.

  Each of the access gateways aGW1 and 2 has a function of MME (Mobility Management Entity) and UPE (User Plane Entity). The MME is a function that performs mobility management control such as location registration area management and paging of each wireless terminal device. UPE is a function for transferring transmission data.

  The radio base station apparatuses eNB1 to eNB3 are connected to the access gateways aGW1 and aGW2 via the interface S1. Moreover, the radio base station apparatuses eNB1 to eNB3 are connected to each other via the interface X2. Each of the radio base station devices eNB1 to eNB3 has corresponding management areas 210, 220, and 230, and performs radio communication with a plurality of radio terminal devices in the corresponding management area. The radio base station apparatuses eNB1 to eNB3 communicate with the radio terminal apparatus by, for example, the OFDM scheme.

  Each of the radio base station apparatuses eNB1 to eNB3 corresponds to the radio base station apparatus 100 illustrated in FIG. Moreover, radio | wireless terminal apparatus UE # 1-UE # 10 ... in the management area 210 respond | corresponds to radio | wireless terminal apparatus UE # 1-UE # 10 ... shown in FIG. The radio base station apparatus eNB1 (hereinafter simply referred to as “radio base station apparatus 100”) and the radio terminal apparatuses # 1 to # 10 in the management area 210 of the radio base station apparatus 100 will be described below.

  FIG. 3 is a diagram illustrating a flow of frame generation by the radio base station apparatus. In FIG. 3, the same parts as those shown in FIG. 1 or FIG. Here, a case where the frame 120 (see FIG. 1) is generated will be described. The access gateway aGW1 (or aGW2) transmits transmission data # 1 to # 7 whose destinations are the radio terminal apparatuses UE # 1 to UE # 7 to the radio base station apparatus 100, respectively.

  First, the radio base station apparatus 100 receives the transmission data # 1 to # 7 transmitted from the access gateway aGW1 and holds it in the buffer 111 (see FIG. 1) (step S311). Next, the respective state checks of the radio terminal apparatuses UE # 1 to UE # 7 that are the destinations of the transmission data # 1 to # 7 held in step S311 are performed (step S312).

  The state of each wireless terminal device checked in step S312 is, for example, the state of establishment of synchronization with the wireless base station device 100, the state of discontinuous reception (DRX: Discontinuous Reception), and the state of whether handoff is in progress. From these states, the radio base station device 100 determines, for each of the radio terminal devices UE # 1 to UE # 7, whether or not the frame 120 transmitted from the radio base station device 100 can be received.

  Here, it is assumed that the radio terminal apparatuses UE # 1 to UE # 4, UE # 6, and UE # 7 have established synchronization with the radio base station apparatus 100 and can receive the frame 120. (OK). On the other hand, the radio terminal apparatus UE # 5 is not in a state in which synchronization with the radio base station apparatus 100 is established and the frame 120 can be received (NG).

  Next, transmission data # 1 to # 4 and # 6 corresponding to the radio terminal apparatuses UE # 1 to UE # 4, UE # 6 and UE # 7 determined to be in a state where the frame 120 can be received in step S312. , # 7, coefficient calculation for determining the priority order is performed (step S313). The coefficients calculated in step S313 are coefficients that combine transmission data priority, transmission data retransmission count, transmission data residence time, and the like.

  The coefficients of the transmission data # 1 to # 4, # 6, and # 7 are calculated so that, for example, transmission data having a higher priority, a larger number of retransmissions, and a longer residence time have a larger coefficient. Here, the coefficients calculated for the transmission data # 1 to # 4, # 6, and # 7 are “10”, “2”, “5”, “8”, “3”, and “6”, respectively. Suppose that

  Next, scheduling for assigning transmission data # 1 to # 4, # 6, and # 7 to the data channel 121 of the frame 120 is performed (step S314). At this time, scheduling is performed preferentially from transmission data having a large coefficient calculated in step S313. In the frame 120, the horizontal axis indicates the band (Hz).

  The vertical axis is the time axis, and time advances from the bottom to the top. The data channel 121 of the frame 120 is divided into resource block groups 320 in which a band and time are divided for each unit amount. The control channel 122 of the frame 120 is provided in the entire band 330 of the frame 120 of the first symbol (or the first and second symbols) of the frame 120.

  The allocating unit 112 acquires quality information in advance for each resource block in the resource block group 320. The allocating unit 112 allocates the transmission data # 1 to # 4, # 6, and # 7 to resource blocks with higher quality in the resource block group 320 as the coefficient increases. Information on the quality of each resource block in the resource block group 320 is acquired by feedback information from each wireless terminal device (see FIGS. 11 and 12).

  Here, in the resource block group 320, it is assumed that the resource blocks having the same bandwidth and different times have the same quality. The allocation unit 112 acquires quality information of each band in the band 330 of the data channel 121 in advance. The assigning unit 112 assigns the transmission data # 1 to # 4, # 6, and # 7 to resource blocks that belong to a high-quality band for the wireless terminal device that is the destination of the transmission data in descending order of the coefficient.

  Next, the storage unit 113 stores allocation information based on the allocation in step S314 in the control channel 122 of the frame 120 (step S315). Specifically, the storage unit 113 code-multiplexes each allocation information indicating which resource block of the resource block group 320 is allocated in step S314 for each of the transmission data # 1 to # 4, # 6, and # 7. And stored in the control channel 122. The storage unit 113 stores various control information different from the allocation information in the control channel 122 together with the allocation information (see FIG. 6).

  FIG. 4 is a diagram (part 1) illustrating a frame generated by the radio base station device according to the first embodiment. FIG. 5 is a diagram (No. 2) illustrating a frame generated by the radio base station device according to the first embodiment. 4 and 5, the same parts as those shown in FIG. 1 or FIG. Similarly to the case illustrated in FIG. 1, the radio base station apparatus 100 generates and transmits a frame 130 after the frame 120.

  First, as illustrated in FIG. 4, the allocating unit 112 transmits transmission data # 1, # 2, and # 3 that are addressed to the radio terminal apparatuses UE # 1 to UE # 3 to the data channel 121 of the frame 120, respectively. assign. The first storage unit 114 stores all allocation information of transmission data # 1 to # 3 in the control channel 122 of the frame 120, as indicated by the dotted line arrows. At this point, it is assumed that the capacity of the control channel 122 is still free.

  The second storage unit 115 detects allocation information exceeding the capacity limit of the control channel 132 among the allocation information of each transmission data allocated to the data channel 131 of the next frame 130. Specifically, first, the second storage unit 115 determines whether or not the total capacity of the allocation information of each transmission data allocated to the data channel 131 exceeds the capacity limit of the control channel 132. An example of a method for determining whether or not the total capacity of each piece of allocation information of each transmission data allocated to the data channel 131 exceeds the capacity limit will be described.

  As a first example, the allocation information of each transmission data held in the buffer 111 at that time is saturated with the capacity limit of the control channel 132, and the total capacity of these transmission data is the capacity limit of the data channel 131. If it is smaller, assuming that new transmission data is held in the buffer 111 immediately thereafter, it is determined that the total capacity of the allocation information of each transmission data allocated to the data channel 131 exceeds the capacity limit.

  Whether the allocation information of each transmission data is saturated with the capacity limit of the control channel 132 is, for example, whether the number of transmission data is a threshold value (for example, 6) corresponding to the capacity limit of the control channel 132. Judgment by As a second example, when the number of transmission data held in the buffer 111 at that time exceeds a threshold (for example, 6) corresponding to the capacity limit of the control channel, each transmission data allocated to the data channel 131 It is determined that the total capacity of each allocation information exceeds the capacity limit.

  As a third example, when the number of transmission data held in the buffer 111 at that time exceeds a threshold (for example, 5) slightly smaller than a threshold (for example, 6) corresponding to the capacity limit of the control channel, Assuming that new transmission data is held in the buffer 111 immediately, it is determined that the total capacity of the allocation information of each transmission data allocated to the data channel 131 exceeds the capacity limit.

  As a fourth example, using the fact that the number of transmission data allocated to one frame is large and the capacity of each transmission data is small, the capacity of the allocation information exceeds the capacity limit of the control channel. Is determined based on the capacity of each piece of transmission data held in the transmission data. Specifically, when the average capacity of each transmission data held in the buffer 111 at that time is smaller than (the capacity of the data channel 131) / (the number of transmission data corresponding to the capacity limit of the control channel 132). Then, it is determined that the total capacity of the allocation information of each transmission data allocated to the data channel 131 exceeds the capacity limit.

  The fourth example may be used only when the number of transmission data allocated to one frame is large. For example, when the number of transmission data held in the buffer 111 is 70% or more of the number corresponding to the capacity limit of the control channel, the determination according to the fourth example is performed. In other cases, it is determined according to the first to third examples, or it is determined that the total capacity of the allocation information of each transmission data allocated to the data channel 131 does not exceed the capacity limit.

  In the fourth example, it is assumed that, for example, (capacity of the data channel 131) / (number of transmission data corresponding to the capacity limitation of the control channel 132) = 10 kbyte / 10 = 1 kbyte. In this case, when the number of transmission data held in the buffer 111 is 3 and the total capacity of each transmission data is 4 kbytes, the average capacity of each transmission data is 4 kbytes / 3 = 1.33... Kbyte ≧ Since it is 1 kbyte, it is determined that the total capacity of each allocation information of each transmission data does not exceed the capacity limit.

  When the number of transmission data held in the buffer 111 is 7 and the total capacity of each transmission data is 6 kbytes, the average capacity of each transmission data is 6 kbytes / 7 = 0.86... Kbyte <1 kbytes. Therefore, it is determined that the total capacity of the allocation information of each transmission data exceeds the capacity limit.

  When the number of transmission data held in the buffer 111 is 8 and the total capacity of each transmission data is 10 kbytes, the average capacity of each transmission data is 10 kbytes / 8 = 1.25 kbytes ≧ 1 kbytes. Then, it is determined that the total capacity of the allocation information of each transmission data does not exceed the capacity limit.

  When it is determined by the above method that the total capacity of the allocation information of each transmission data allocated to the data channel 131 exceeds the capacity limit, as illustrated in FIG. Transmission data # 4 to # 12 whose destinations are the wireless terminal apparatuses UE # 4 to UE # 12 are allocated to the channel 131, respectively.

  Here, it is assumed that the total capacity of the transmission data # 4 to # 9 among the transmission data # 4 to # 12 allocated to the frame 130 is within the capacity limit of the control channel 132. Further, it is assumed that any capacity of transmission data # 10 to # 12 is added to the total capacity of the allocation information of transmission data # 4 to # 9, so that the capacity limit of control channel 132 is exceeded.

  In this case, the second storage unit 115 detects the allocation information of the transmission data # 10 to # 12 as allocation information exceeding the capacity limit of the control channel 132. The second storage unit 115 stores each piece of allocation information of the detected transmission data # 10 to # 12 in the control channel 122 of the frame 120, as indicated by the dotted arrow. Further, the second storage unit 115 stores, in the control channel 122, information indicating that the allocation information of the transmission data # 10 to # 12 allocated to the data channel 131 of the frame 130 is stored in the control channel 122 of the frame 120. .

  FIG. 6 is a diagram illustrating an example of control information stored in the control channel illustrated in FIG. As shown in FIG. 6, the control information 610 stored in the control channel 122 of the frame 120 includes format information 611, downlink control information 612, uplink individual control information 613, uplink common control information 614, It is composed of

  The format information 611 is an identifier indicating the size of each piece of information in the downlink control information 612, the uplink individual control information 613, and the uplink common control information 614, and the like. The downlink control information 612 includes allocation information indicating resource blocks to which transmission data is allocated in the data channel, modulation scheme and size of transmission data, and HARQ (Hybrid Automatic Repeat request) information for performing automatic retransmission control. In addition, a UE-ID indicating a destination wireless terminal device of transmission data is stored.

  Further, in the downlink control information 612, when the allocation information stored in the downlink control information 612 is allocation information of transmission data allocated to a frame different from the frame 120, flag information indicating that fact. And frame identification information indicating the different frames is stored. For example, in the case described with reference to FIG. 5, flag information and frame identification information indicating the frame 130 are stored in the format information 611 of the control channel 122.

  The uplink individual control information 613 stores individual control information for the wireless terminal device that has requested data transmission. The uplink individual control information 613 stores uplink band allocation information, information indicating a permitted modulation scheme, data size and transmission power, UE-ID indicating a target wireless terminal device, and the like. The uplink common control information 614 includes ACK / NACK information for transmission confirmation, feedback information such as TCP (Transmission Control Protocol) information, and the like.

  FIG. 7 is a flowchart of an operation of the radio base station apparatus according to the first embodiment. Here, an operation of generating and transmitting the frames 120 and 130 shown in FIGS. 4 and 5 will be described. As shown in FIG. 7, the assigning unit 112 first checks the state of each wireless terminal device that is the destination of each transmission data read from the buffer 111 (step S701).

  Next, the allocating unit 112 performs coefficient calculation for allocating each transmission data destined for each wireless terminal device determined to be in a state in which the frame 120 can be received in step S701 to the frame 120 to be transmitted ( Step S702). Next, transmission data is assigned to the data channel 121 of the frame 120 to be transmitted based on the coefficient calculated in step S703 (step S703).

  Next, the storage unit 113 stores allocation information based on the allocation in step S703 in the control channel 122 of the frame 120 to be transmitted (step S704). Next, it is determined whether or not there is a free capacity in the control channel 122 of the frame 120 to be transmitted (step S705). If there is no free capacity in the control channel 122 of the frame 120 (step S705: No), the process proceeds to step S713 to continue the process.

  If the capacity of the control channel 122 of the frame 120 is free in step S705 (step S705: Yes), it is determined whether there is transmission data in the buffer 111 at that time (step S706). When there is no transmission data in the buffer 111 (step S706: No), it progresses to step S713 and continues a process.

  In step S706, when there is transmission data in the buffer 111 (step S706: Yes), the total capacity of the allocation information of each transmission data allocated to the data channel 131 of the next frame 130 of the frame 120 to be transmitted is the frame 130. It is determined whether or not the capacity limit of the control channel 132 is exceeded (step S707).

  If it is determined in step S707 that the total capacity of the allocation information does not exceed the capacity limit of the control channel 132 of the frame 130 (step S707: No), the process proceeds to step S713 and the process is continued. When it is determined that the total capacity of each allocation information exceeds the capacity limit of the control channel 132 (step S707: Yes), the state of each wireless terminal device that is the destination of each transmission data in the buffer 111 is checked (step S708). .

  Next, in step S708, coefficient calculation for allocating the transmission data destined for each wireless terminal device determined to be capable of receiving the next frame 130 of the frame 120 to be transmitted to the frame 130 is performed. (Step S709). Next, each transmission data is allocated to the data channel 131 of the next frame 130 based on each coefficient calculated by step S709 (step S710).

  Next, of the allocation information based on the allocation in step S710, allocation information exceeding the capacity limit of the control channel 132 of the next frame 130 is stored in the control channel 122 of the frame 120 to be transmitted (step S711). Next, information (flag information and frame identification information) for transmitting each allocation information of transmission data # 10 to # 12 allocated to the data channel 131 of the frame 130 in the control channel 122 of the frame 120 is transmitted. The data is stored in the control channel 122 of the frame 120 (step S712).

  Next, the transmission part 116 transmits the flame | frame 120 to each radio | wireless terminal apparatus UE # 1-UE # 12 (step S713), and complete | finishes a series of processes. When the capacity of the control channel 122 of the frame 120 before the target frame 130 is free by the above steps, the allocation exceeding the capacity limit of the control channel 132 among the allocation information of each transmission information allocated to the frame 130 Information can be stored in the control channel 122 of the frame 120.

  Thus, according to the radio base station apparatus 100 according to the first embodiment, the allocation information exceeding the capacity limit of the control channel 132 among the allocation information of each transmission information allocated to the target frame 130 is changed to the previous frame. 120 control channels 122 can be stored. As a result, if there is a free space in the data channel 131, transmission data can be allocated exceeding the capacity limit of the control channel 132. For this reason, transmission data can be allocated to the data channel 131 without waste, and radio resources can be used efficiently.

(Embodiment 2)
FIG. 8 is a diagram of a frame generated by the radio base station apparatus according to the second embodiment. The radio communication system 200 (see FIG. 2) to which the radio base station apparatus 100 according to the second embodiment is applied and the flow of frame generation (see FIG. 3) by the radio base station apparatus 100 are the radio base according to the first embodiment. Since it is the same as the station apparatus 100, description is abbreviate | omitted. 8, parts similar to those shown in FIGS. 4 and 5 are given the same reference numerals and description thereof is omitted.

  Similarly to the case illustrated in FIG. 4, the radio base station apparatus 100 generates and transmits a frame 130 after the frame 120. The allocation unit 112 allocates each transmission data to the data channel 121 of the frame 120 within the capacity limit of the data channel 121. Here, allocating section 112 allocates transmission data # 1 to # 9, which are addressed to radio terminal apparatuses UE # 1 to UE # 9, to data channel 121, respectively.

  The first storage unit 114 stores, in the control channel 122, allocation information within the capacity limit of the control channel 122 among the transmission data # 1 to # 9. Here, it is assumed that the total capacity of the transmission data # 1 to # 6 of the transmission data # 1 to # 9 is within the capacity limit of the control channel 122. Further, it is assumed that any capacity of transmission data # 7 to # 9 is added to the total capacity of the allocation information of transmission data # 1 to # 6 and the capacity limit of control channel 122 is exceeded.

  In this case, the first storage unit 114 stores the allocation information of the transmission data # 1 to # 6 in the control channel 122 as indicated by the dotted line arrows. The second storage unit 115 stores the allocation information exceeding the capacity limit of the control channel 122 among the transmission data # 1 to # 9 in the control channel 132 of the frame 130 next to the frame 120. Here, the second storage unit 115 stores the allocation information of the transmission data # 7 to # 9 in the control channel 132 as indicated by the dotted line arrows.

  Further, the allocating unit 112 transmits the second transmission data # 1 (2) destined for the radio terminal apparatus UE # 1 and the radio terminal apparatus UE # 2 to the data channel 131 of the frame 130 subsequent to the frame 120. The second transmission data # 2 (2) destined for and the second transmission data # 3 (2) destined for the radio terminal apparatus UE # 3 are allocated.

  The first storage unit 114 stores, in the control channel 132, allocation information within the capacity limit of the control channel 132 among the transmission data allocated to the data channel 131 of the frame 130. Here, it is assumed that the total capacity of transmission data # 1 (2), # 2 (2), and # 3 (2) assigned to the frame 130 is within the capacity limit of the control channel 132. In this case, the first storage unit 114 stores the transmission data # 1 (2), # 2 (2), and # 3 (2) in the control channel 132 as indicated by the dotted line arrows.

  FIG. 9 is a diagram showing an example of control information stored in the control channel shown in FIG. In FIG. 2, the same parts as those shown in FIG. As shown in FIG. 9, the control information 910 stored in the control channel 122 of the frame 120 includes retained extraction information 911, format information 611, downlink control information 612, uplink individual control information 613, and uplink. Common control information 614.

  When the transmission data allocation information allocated to the data channel 121 of the frame 120 is stored in a different frame from the frame 120, the hold extraction information 911 includes flag information indicating that fact and the different frame. Is stored. Further, the hold extraction information 911 stores a UE-ID indicating the destination of the target transmission data together with the flag information and the frame identification information.

  In the case described with reference to FIG. 8, the hold extraction information 911 includes flag information, frame identification information indicating the frame 130, and UE− indicating the radio terminal apparatuses UE # 7 to UE # 9 that are destinations of the target transmission data. ID is stored. In this case, when each of the radio terminal apparatuses UE # 7 to UE # 9 receives the frame 120, since the flag information is stored in the hold extraction information 911 of the control channel of the frame 120, the received frame 120 And wait for reception of the frame 130 indicated by the frame identification information stored in the hold extraction information 911.

  Then, when each of the wireless terminal apparatuses UE # 7 to UE # 9 receives the frame 130, each of the transmission data from the held frame 120 is based on the allocation information stored in the control channel 132 of the frame 130. # 7 to # 9 are acquired. Note that the flag information and the frame identification information described in FIG. 6 are not stored in the downlink control information 612 of the control information 910 of the control channel 122.

  FIG. 10-1 is a flowchart (part 1) illustrating an operation of the radio base station apparatus according to the second embodiment. FIG. 10-2 is a flowchart (part 2) of the operation of the radio base station apparatus according to the second embodiment. Here, an operation when the frames 120 and 130 shown in FIG. 8 are generated and transmitted will be described. As illustrated in FIG. 10A, the allocating unit 112 first checks the state of each wireless terminal device that is the destination of each transmission data read from the buffer 111 (step S1001).

  Next, the allocating unit 112 performs coefficient calculation for allocating to the frame 120 to be transmitted for each wireless terminal device determined to be in a state where the frame 120 can be received in step S1001 (step S1002). Next, the assigning unit 112 assigns transmission data to the frame 120 to be transmitted based on the coefficient calculated in step S1002 (step S1003).

  Next, the allocation unit 112 stores allocation information based on the allocation in step S1003 in the control channel 122 of the frame 120 to be transmitted (step S1004). Next, it is determined whether or not there is a free capacity in the control channel 122 of the frame 120 to be transmitted (step S1005). If there is no free space in the control channel 122 (step S1005: No), the process proceeds to step S1009 to continue the processing.

  In step S1005, when the capacity of the control channel 122 is empty (step S1005: Yes), the transmission information of each transmission data allocated to the data channel of the frame before the frame 120 is not transmitted (which control It is determined whether there is allocation information that is not stored in the channel (step S1006). If there is no unsent allocation information (step S1006: No), the process proceeds to step S1008 to continue the process.

  If there is unsent allocation information in step S1006 (step S1006: Yes), the unsent allocation information is stored in the control channel 122 of the frame 120 to be transmitted (step S1007). Next, it is determined whether or not there is a free capacity in the control channel 122 of the frame 120 to be transmitted (step S1008). If there is a free space (step S1008: Yes), the process proceeds to step S1015 in FIG.

  In step S1008, when there is no free space in the control channel 122 (step S1008: No), the process proceeds to step S1009 in FIG. 10-2 (reference B), and it is determined whether or not there is transmission data in the buffer 111 ( Step S1009). When there is no transmission data in the buffer 111 (step S1009: No), it progresses to step S1015 and continues a process. When there is transmission data in the buffer 111 (step S1009: Yes), it is determined whether or not the capacity of the data channel 121 of the frame 120 to be transmitted is free (step S1010).

  In step S1010, when there is a free space in the data channel 121 (step S1010: Yes), the state of each wireless terminal device that is the destination of each transmission data in the buffer 111 is checked (step S1011). Next, for each wireless terminal device determined to be in a state where the frame 120 can be received in step S1011, coefficient calculation for assigning to the frame 120 to be transmitted is performed (step S1012).

  Next, each transmission data is assigned to the data channel 121 of the frame 120 to be transmitted based on the coefficient calculated in step S1012 (step S1013). Next, information (flag information and frame identification information) for storing the transmission data allocation information allocated in step S1013 in the control channel 132 of the next frame 130 is stored in the control channel 122 of the frame 120 to be transmitted ( In step S1014), the process returns to step S1009 to continue the processing.

  In step S1010, when there is no space in the capacity of the data channel 121 (step S1010: No), the frame 120 is transmitted to each wireless terminal device (step S1015), and a series of processing ends. Through the above steps, the allocation information exceeding the capacity limit of the control channel 122 among the allocation information of each transmission information allocated to the frame 120 can be stored in the control channel 132 of the frame 130 next to the frame 120.

  Thus, according to the radio base station apparatus 100 according to the second embodiment, the allocation information exceeding the capacity limit of the control channel 122 among the allocation information of each transmission information allocated to the target frame 120 is transmitted to the next frame. 130 control channels 132 can be stored. As a result, if there is a free space in the data channel 121, transmission data can be allocated exceeding the capacity limit of the control channel 122. For this reason, transmission data can be allocated to the data channel 131 without waste, and radio resources can be used efficiently.

  FIG. 11 is a diagram illustrating a reference signal transmitted by the radio base station apparatus. The radio base station apparatus 100 transmits a reference signal 1100 as shown in FIG. 11 to each radio terminal apparatus before allocation of each transmission data to the resource block group 320 by the allocation unit 112. The reference signal 1100 is a signal in which a signal R having a predetermined pattern is assigned to the resource block group 320.

  FIG. 12 is a diagram illustrating feedback information transmitted by the wireless terminal device. Each wireless terminal device that has received the reference signal 1100 (see FIG. 11) from the wireless base station device 100 divides the band 330 of the reference signal 1100 into groups G # 1 to G # 8, and signals in each divided group. CQI (Channel Quality Indicator: radio quality) is calculated from the received quality of R.

  Each wireless terminal apparatus transmits feedback information 1200 indicating the calculated CQI for each of groups G # 1 to G # 8 to wireless base station apparatus 100. Here, the CQIs for the groups G # 1 to G # 8 indicated by the feedback information 1200 are “3”, “10”, “20”, “15”, “18”, “13”, “9”, respectively. It is “14”.

  Allocation unit 112 of radio base station apparatus 100 has the highest CQI in resource block group 320 for transmission data destined for the radio terminal apparatus that transmitted feedback information 1200 (herein, transmission data # 1). It is determined whether other transmission data is allocated to the resource block belonging to group G # 3.

  When other transmission data is not allocated to the resource block belonging to group G # 3, allocation section 112 allocates transmission data # 1 to the resource block belonging to group G # 3, and other transmission data is allocated. If there is, it is determined whether other transmission data is allocated to the resource block belonging to the group G # 5 having the second highest CQI.

  Similarly, allocating unit 112 selects a group of resource blocks to which transmission data is allocated in the order of groups G # 5, G # 4, G # 8, G # 6, G # 2, G # 7, and G # 1. . For each piece of transmission data to be allocated, allocation section 112 acquires feedback information 1200 transmitted from the destination wireless terminal apparatus of the transmission data, and transmits the transmission data to a resource block having a high CQI indicated by the acquired feedback information 1200. Assign with priority.

  As described above, according to the disclosed radio base station apparatus, radio terminal apparatus, and radio communication method, radio resources can be used efficiently.

It is a figure which shows the outline | summary of the radio base station apparatus concerning embodiment. 1 is a block diagram showing a configuration of a wireless communication system according to a first exemplary embodiment. It is a figure which shows the flow of the frame production | generation by a radio base station apparatus. FIG. 3 is a diagram (part 1) illustrating a frame generated by the radio base station device according to the first embodiment; FIG. 6 is a diagram (part 2) illustrating a frame generated by the radio base station device according to the first embodiment; It is a figure which shows an example of the control information stored in the control channel shown in FIG. 3 is a flowchart showing an operation of the radio base station apparatus according to the first exemplary embodiment; FIG. 6 is a diagram illustrating a frame generated by the radio base station apparatus according to the second embodiment. It is a figure which shows an example of the control information stored in the control channel shown in FIG. 10 is a flowchart (part 1) illustrating an operation of the radio base station apparatus according to the second embodiment; 6 is a flowchart (part 2) illustrating an operation of the radio base station apparatus according to the second embodiment; It is a figure which shows the reference signal which a radio base station apparatus transmits. It is a figure which shows the feedback information which a wireless terminal device transmits.

Explanation of symbols

100 radio base station apparatus 120, 130 frame 121, 131 data channel 122, 132 control channel 200 radio communication system 210, 220, 230 management area 320 resource block group 330 band 610, 910 control information 911 holding extraction information 1100 reference signal 1200 feedback information

Claims (10)

In a radio base station apparatus that sequentially transmits frames to which each transmission data is assigned to a plurality of radio terminal apparatuses to the plurality of radio terminal apparatuses,
Allocating means for allocating each transmission data to a data channel of a target frame;
First storage means for storing, in the control channel, allocation information within the capacity limit of the control channel of the target frame among the allocation information of the transmission data by the allocation means;
Second storage means for storing allocation information exceeding the capacity limit among the allocation information in a control channel of a frame different from the target frame;
Transmitting means to which each of the transmission data is allocated, and to transmit the frame storing the allocation information to the plurality of wireless terminal devices;
A radio base station apparatus comprising:   The second storage means stores information for identifying a frame to be transmitted after each of the frames in a control channel of a frame to be transmitted first among the frames of the target frame and the different frames. The radio base station apparatus according to claim 1, wherein:   The radio base station apparatus according to claim 1, wherein the second storage unit stores allocation information exceeding the capacity limit in a control channel of a frame preceding the target frame.   The second storage means detects allocation information that exceeds the capacity limit of the target frame when there is a vacancy in the control channel capacity of the previous frame in which the allocation information is stored by the first storage means. The radio base station apparatus according to claim 3, wherein the detected allocation information is stored in a control channel of the previous frame.   The second storage means stores, in the control channel of the previous frame, information indicating that allocation information exceeding the capacity limit of the control channel of the target frame is stored in the control channel of the previous frame. The radio base station apparatus according to claim 3.   The radio base station apparatus according to claim 1, wherein the second storage unit stores allocation information exceeding the capacity limit in a control channel of a frame next to the target frame.   The said 2nd storage means stores the information which shows storing the allocation information exceeding the said capacity | capacitance limitation in the control channel of the said following flame | frame in the control channel of the said object frame, It is characterized by the above-mentioned. Wireless base station equipment. Receiving means for sequentially receiving, from the radio base station apparatus, a frame in which each transmission data is assigned to a plurality of radio terminal apparatuses;
Allocation information that exceeds the capacity limit of the control channel of the subsequent frame among the allocation information of the transmission data allocated to the subsequent frame of the received frame from the control channel of the frame received by the receiving unit, Extraction means for extracting information indicating storage in the control channel of the received frame;
An acquisition means for acquiring transmission data addressed to the own apparatus allocated to the subsequent frame, using allocation information stored in a control channel of the received frame, based on the information extracted by the extraction means; ,
A wireless terminal device comprising: Receiving means for sequentially receiving, from the radio base station apparatus, a frame in which each transmission data is assigned to a plurality of radio terminal apparatuses;
From the control channel of the frame received by the receiving means, the allocation information exceeding the capacity limit of the control channel of the received frame among the allocation information of transmission data allocated to the received frame is received. Extracting means for extracting information indicating storage in a control channel of a frame after the frame;
Obtaining means for obtaining transmission data assigned to the received frame and assigned to the received frame, using assignment information stored in a control channel of the subsequent frame, based on the information extracted by the extracting means; ,
A wireless terminal device comprising: In a radio communication method of a radio base station for sequentially transmitting frames to which a plurality of radio terminal devices are assigned transmission data to the plurality of radio terminal devices,
An assigning step of assigning each of the transmission data to a data channel of a target frame;
A first storage step of storing, in the control channel, allocation information within the capacity limit of the control channel of the target frame among the allocation information of the transmission data by the allocation step;
A second storage step of storing allocation information exceeding the capacity limit among the allocation information in a control channel of a frame different from the target frame;
A transmission step in which each of the transmission data is allocated and a frame in which the allocation information is stored is transmitted to the plurality of wireless terminal devices;
A wireless communication method comprising:

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