JP4955080B2 - Reception station, transmission station, mobile communication system, and frequency block allocation method - Google Patents

Description

  The present invention relates to a receiving station, a transmitting station, a mobile communication system, and a frequency block allocation method that divide the entire system band into a plurality of frequency blocks and allocate radio resources for each block.

  A signal propagated through a multipath environment such as mobile communication is affected by frequency selective fading. As a result, the amount of phase rotation and received power for each subcarrier varies.

  Moreover, the fluctuation | variation changes with the environment and frequency of a propagation path, and frequency selectivity is independent between users. That is, depending on the frequency, there are users who have good reception channel conditions, for example, good SIR (Signal-to-Interference Power Ratio) and bad users.

  For this reason, in a multicarrier system such as OFDM (Orthogonal Frequency Division Multiplexing) and OFCDM (Orthogonal Frequency and Code Division Multiplexing), the entire frequency band allocated to the system is divided into a plurality of frequency blocks, and each divided frequency block is divided. Frequency scheduling for allocating radio resources to the network has been studied.

  Frequency scheduling will be described with reference to FIG.

  In the frequency characteristics of the reception channel state shown in FIG. 1, the horizontal axis represents frequency, the vertical axis represents the reception channel state, and the horizontal axis is further divided into frequency blocks 1 to 4.

  According to the frequency characteristics of the reception channel state, it can be seen that the occurrence of fading differs depending on the frequency and that the occurrence of fading is independent for each user. That is, it shows that the reception channel state of each user at a certain frequency may be different.

  Therefore, in this case, frequency bands with good reception channel conditions for User1, such as frequency blocks 1 and 2, are assigned to Uesr1, and frequency bands with good reception channel conditions for User2, such as frequency blocks 3 and 4, are assigned to Uesr2. By performing frequency scheduling in this way, the throughput of the entire system can be increased.

  Of the conventional techniques described above, frequency scheduling is not known in the literature as long as the applicant knows at the time of filing.

  Further, the applicant has not been able to find prior art documents related to the present invention by the time of filing. Therefore, prior art document information is not disclosed.

  However, the background art described above has the following problems.

  When performing frequency scheduling, the receiving station needs to notify the transmitting station of control information indicating a receiving channel state for each frequency block by the control channel. However, there is a problem that the overhead of the control bit in this control information is large and the control bit itself increases, resulting in a decrease in the throughput of the entire system.

  Moreover, when assigning frequency blocks to users, there is a problem that users with many frequency blocks to be assigned and users with few frequency blocks are generated.

  Accordingly, an object of the present invention is to provide a mobile communication system, a receiving station, a transmitting station, and a frequency block allocation method that can improve the throughput of the mobile communication system.

This receiving station
A receiving unit for receiving information indicating a frequency block distributed by the transmitting station ;
A reception channel state measurement unit for measuring a reception channel state of the frequency block based on information indicating the frequency block received by the reception unit ;
A control information generation unit that generates control information indicating a reception channel state of the frequency block to be notified to the transmission station based on the reception channel state measured by the reception channel state measurement unit;
The transmitting station, obtain Preparations and a notification unit configured to notify the control information generated by the control information generating unit.

This transmitting station
A distribution unit that distributes a plurality of receiving stations to a frequency block obtained by dividing the frequency band ;
A notification unit for notifying the plurality of receiving stations of information indicating the frequency blocks distributed by the distribution unit;
It said plurality of based on the control information indicating the reception channel state notified the frequency blocks from the receiving station obtains an index related to the allocation of radio resources in the frequency block for each of the receiving stations, based on the indicator, the time domain And a scheduler for performing scheduling .

This mobile communication system
A mobile communication system comprising a transmitting station and a receiving station,
The receiving station is
A receiving unit for receiving information indicating a frequency block distributed by the transmitting station ;
A reception channel state measurement unit for measuring a reception channel state of the frequency block based on information indicating the frequency block received by the reception unit ;
A control information generation unit that generates control information indicating a reception channel state of the frequency block to be notified to the transmission station based on the reception channel state measured by the reception channel state measurement unit;
A notification unit for notifying the transmission station of the control information generated by the control information generation unit ,
Before Symbol transmitting station,
A distribution unit that distributes a plurality of receiving stations to a frequency block obtained by dividing the frequency band ;
A notification unit for notifying the plurality of receiving stations of information indicating the frequency blocks distributed by the distribution unit;
It said plurality of based on the control information indicating the reception channel state notified the frequency blocks from the receiving station obtains an index related to the allocation of radio resources in the frequency block for each of the receiving stations, based on the indicator, the time domain obtain Bei a scheduler to perform scheduling.

This frequency block allocation method is
A transmitting station, a frequency block allocation method in a mobile communication system and a receiving station,
The receiving station is
A receiving step for receiving information indicating a frequency block distributed by the transmitting station ;
Measuring a reception channel state of the frequency block based on information indicating the frequency block received by the reception step ;
Generating control information indicating the reception channel state of the frequency block to be notified to the transmitting station based on the reception channel state measured by the step of measuring the reception channel state;
Notifying the transmitting station of the control information generated by the step of generating the control information,
The transmitting station is
Distributing a plurality of receiving stations to a frequency block obtained by dividing a frequency band ;
A notification step of notifying the plurality of receiving stations of information indicating the frequency block allocated by the distributing step;
Based on the control information indicating the reception channel state notified the frequency blocks from said plurality of receiving stations, seeking index regarding the allocation of radio resources in the frequency block in each of the receiving stations, based on the indicator, in the time domain It has a step of performing the scheduling.

  According to the embodiments of the present invention, it is possible to realize a mobile communication system, a receiving station, a transmitting station, and a frequency block allocation method that can improve the throughput of the mobile communication system.

It is explanatory drawing for demonstrating frequency scheduling. It is a block diagram for demonstrating the structure of the transmission station in the mobile communication system concerning the Example of this invention. It is a block diagram for demonstrating the structure of the transmission station in the mobile communication system concerning the Example of this invention. It is a block diagram for demonstrating the structure of the receiving station in the mobile communication system concerning the Example of this invention. It is explanatory drawing for demonstrating the control information which the receiving station in the mobile communication system concerning the Example of this invention transmits, (a) is a case where the receiving channel state etc. of a top N block with a favorable receiving channel state are notified , (B) is a case in which the reception channel state of the frequency block is notified at M block intervals. It is explanatory drawing for demonstrating the control information which the receiving station in the mobile communication system concerning the Example of this invention transmits, (a) is the average receiving channel state of all the subcarriers, and the receiving channel in each subcarrier When notifying the difference with respect to the average of a state, (b) is a case where ID of the frequency block arranged in order with the favorable reception channel state is notified. It is explanatory drawing for demonstrating the control information which the receiving station in the mobile communication system concerning the Example of this invention transmits, and is the case where ID of the frequency block with a bad receiving channel state is notified. It is explanatory drawing for demonstrating the receiving channel state which the receiving station measures in the mobile communication system concerning the Example of this invention, (a) is the average receiving SIR of 1 frequency block, (b) is the average of all the frequency blocks. Reception SIR, (c) is an average reception SIR obtained by further averaging the average reception SIR of one frequency block, and (d) is an average reception SIR obtained by further averaging the average reception SIR of all frequency blocks. It is explanatory drawing for demonstrating the frequency block allocation method in the transmission station of the mobile communication system concerning the Example of this invention. It is a flowchart for demonstrating the creation flow of the ranking table of each frequency block in the transmission station of the mobile communication system concerning the Example of this invention. It is a flowchart for demonstrating the allocation flow of the frequency block in the transmission station of the mobile communication system concerning the Example of this invention. It is explanatory drawing for demonstrating the ranking table in the transmission station of the mobile communication system concerning the Example of this invention. It is a flowchart for demonstrating the allocation flow of the frequency block in the transmission station of the mobile communication system concerning the Example of this invention. It is explanatory drawing which shows allocation of the frequency block in the transmission station of the mobile communication system concerning the Example of this invention. It is a block diagram for demonstrating the structure of the transmission station in the mobile communication system concerning the Example of this invention. It is a flowchart for demonstrating the allocation flow of the frequency block in the transmission station of the mobile communication system concerning the Example of this invention. It is a block diagram for demonstrating the structure of the transmission station in the mobile communication system concerning the Example of this invention. It is a flowchart for demonstrating the allocation flow of the frequency block in the transmission station of the mobile communication system concerning the Example of this invention. It is explanatory drawing for demonstrating the case where the frequency block in which the receiving state in the transmitting station of the mobile communication system concerning the Example of this invention is not notified is allocated, (a) is the frequency with which the receiving channel state was notified in the past. When priority is given to the block, (b) is a case where priority is given to a block adjacent to the block notified of the reception channel state information. It is explanatory drawing for demonstrating the case where the frequency block to which the receiving status information is not notified in the transmitting station of the mobile communication system concerning the Example of this invention is allocated, (a) is from the block to which the receiving channel state was notified. When priority is given to blocks that are L blocks away, (b) is when priority is given to blocks that are more than L blocks away from blocks with poor reception channel conditions. It is explanatory drawing for demonstrating the blocking in the transmission station of the mobile communication system concerning the Example of this invention, (a) is a case where adjacent subcarriers are collectively blocked and (b) is separated by a fixed number of carriers. When subcarriers are blocked, (c) is a case where a plurality of blocks are grouped together. It is explanatory drawing for demonstrating utilization of the code area | region in the transmission station of the mobile communication system concerning the Example of this invention, (a) is a case where the code channel which makes a frequency block, and the code channel which is not made, are provided, (b) Is a case where the remaining code channel of the frequency block to which the user is allocated is allocated to another user. It is explanatory drawing for demonstrating utilization of the frequency domain in the transmission station of the mobile communication system concerning the Example of this invention.

  Next, embodiments of the present invention will be described with reference to the drawings. In all the drawings for explaining the embodiments, the same reference numerals are used for those having the same function, and repeated explanation is omitted.

  The mobile communication system according to the first embodiment of the present invention includes a transmitting station 100 and a receiving station 200.

  Next, the configuration of the transmitting station in the mobile communication system according to the present embodiment will be described with reference to FIG.

  The transmitting station 100 in the mobile communication system according to the present embodiment is connected to the RF receiving circuit 100-1, the demodulation / decoding unit 100-2 connected to the RF receiving circuit 100-1, and the demodulation / decoding unit 100-2. Scheduler 100-3, header information acquisition unit 100-4, packet selection unit 100-5 connected to the header information unit 100-4, header information acquisition unit 100-4, packet selection unit 100-5, and A buffer management unit 100-6 connected to the scheduler 100-3, a PDU (Protocol Data Unit) generation unit 100-7 connected to the packet selection unit 100-5, a PDU generation unit 100-7, and a buffer management unit 100 Transmission buffer 100-8 connected to -6, selector 100-9 connected to transmission buffer 100-8 and scheduler 100-3, selector It comprises one or a plurality of coding and modulation unit 100-10 coupled with the 00-9, and a RF transmission circuit 100-11 coupled with the encoding and modulation unit 100-10.

  A control signal including control information from each receiving station 200 is received by the RF receiving circuit 100-1, and the received control signal is input to the demodulation / decoding unit 100-2. The demodulation / decoding section 100-2 performs control signal demodulation / decoding processing, and notifies the scheduler 100-3 of uplink control information (downlink reception channel state for each frequency block) of each receiving station.

  On the other hand, when an IP packet transmitted from the network is received, the header information acquisition unit 100-4 acquires packet header information such as a destination address from the received IP packet, and uses the acquired packet header information as a buffer management unit. 100-6 is notified, and the IP packet is input to the packet sorting unit 100-5.

  Based on the notified packet header information and the status of each queue notified from the transmission buffer 100-8, which will be described later, the buffer management unit 100-6 determines the packet data storage destination for the packet selection unit 100-5. specify. Also, the buffer management unit 100-6 inputs the destination address and the memory address of the queue corresponding to the address to the transmission buffer 100-8. The buffer management unit 100-6 notifies the scheduler 100-3 of the status of each queue notified from the packet header information and the transmission buffer 100-8.

  The packet sorting unit 100-5 sorts the input IP packet based on the storage location of the packet data designated by the buffer management unit 100-6, and inputs the selected packet to the PDU generation unit 100-7. . The PDU generation unit 100-7 converts the input packet into a PDU and inputs the packet to the transmission buffer 100-8.

  The transmission buffer 100-8 creates an independent queue for each destination (receiving station) from the input PDU based on the destination address input by the buffer management unit 100-6 and the memory address of the corresponding queue. The status of each queue is notified to the buffer management unit 100-6.

  The selector 100-9 extracts data from the queue designated by the scheduler 100-3 and inputs the data to the encoding / modulation unit 100-10 for the designated frequency block. This frequency block is allocated by the scheduler 100-3. Based on the notified uplink control information (downlink reception channel state for each frequency block), packet header information, and the state of each queue, the scheduler 100-3 assigns the frequency block to each user. An index (priority) is obtained, and frequency block allocation is determined based on the index.

  The input data is encoded / modulated in the encoding / modulation section 100-10, and the encoded / modulated data is transmitted to each receiving station by the RF transmission circuit 100-11.

  In the transmitting station 100 described above, a case has been described in which the input packet is divided and converted into a PDU in the PDU generation unit 100-7, and then the PDU is stored in the transmission buffer 100-8. As shown, one or a plurality of PDU generation units 100-7 are arranged between the selector 100-9 and the encoding / modulation unit 100-10, and data to be transmitted in each frequency block is designated by the selector 100-9. After being taken out from the queue, the taken out data may be divided into PDUs.

  In this case, the packet sorting unit 100-5 sorts the input IP packet based on the storage location of the packet data designated by the buffer management unit 100-6, and sends it to the transmission buffer 100-8 for each sorted packet. input. The transmission buffer 100-8 forms an independent queue for each destination (receiving station) from the input packet, and notifies the buffer management unit 100-6 of the state of each queue. The transmission buffer 100-8 inputs the formed queue to the selector 100-9.

  The selector 100-9 extracts data to be transmitted in each frequency block from the input queue. In this case, the frequency block is allocated by the scheduler 100-3. The extracted queue is input to one or a plurality of PDU generation units 100-7 for each queue. The PDU generation unit 100-7 converts the input packet into a PDU, and inputs the PDU-converted packet to one or a plurality of encoding / modulation units 100-10.

  Next, the configuration of the receiving station in the mobile communication system according to the present embodiment will be described with reference to FIG.

  The receiving station 200 in the mobile communication system according to the present embodiment includes an RF receiving circuit 200-1, a subcarrier signal separating unit 200-2 connected to the RF receiving circuit 200-1, and a subcarrier signal separating unit 200-2. Channel estimation unit 200-3 connected to the subcarrier signal separation unit 200-2 and one or more reception channel state measurement units 200-4 connected to the channel estimation unit 200-3, and one or more receptions A feedback data generation unit 200-5 connected to the channel state measurement unit 200-4, an encoding / modulation unit 200-6 connected to the feedback data generation unit 200-5, and an encoding / modulation unit 200-6; The connected RF transmission circuit 200-7, one or more demodulation units 200-8 connected to the subcarrier signal separation unit 200-2, and one or more One or more decoding units 200-9 respectively connected to the modulation unit 200-8, a parallel-serial conversion unit 200-10 connected to one or more decoding units 200-9, and a parallel-serial conversion unit 200-10 And an IP packet restoration unit 200-11 connected to each other.

  The transmission signal transmitted from the transmission station 100 is received by the RF reception circuit 200-1. The RF reception circuit 200-1 inputs the reception signal to the subcarrier signal separation unit 200-2. Subcarrier signal separation section 200-2 separates the received signal into signals for each subcarrier, and separates the signals for each subcarrier into one or more demodulation sections 200-8 for each subcarrier, and for each subcarrier. The data is input to one or a plurality of reception channel state measurement units 200-4. Subcarrier signal separation section 200-2 inputs the separated signal for each subcarrier to channel estimation section 200-3.

  Each demodulator 200-8 demodulates the input signal for each subcarrier, and inputs the demodulated signal to one or a plurality of decoders 200-9 for each demodulated signal. Each decoding unit 200-9 decodes the input signal and inputs the decoded signal to the parallel-serial conversion unit 200-10. The parallel-serial conversion unit 200-10 performs parallel-serial conversion on the input signal and inputs the input signal to the IP packet restoration unit 200-11. The IP packet restoration unit 200-11 restores the input signal.

  On the other hand, channel estimation section 200-3 performs channel estimation using pilot symbols for each subcarrier, and inputs a channel estimation value for each subcarrier to one or a plurality of reception channel state measurement sections 200-4.

  Each reception channel state measurement unit 200-4 measures a reception channel state, for example, SIR based on the input signal and channel estimation value for each subcarrier, and inputs the measurement value to the feedback data generation unit 200-5. To do. The feedback data generation unit 200-5 generates feedback data (control information) indicating the reception channel state of the frequency block based on the input measurement value of the reception channel state, and encodes / modulates the generated feedback data Enter 200-6. The encoding / modulation unit 200-6 encodes / modulates the input feedback data and inputs it to the RF transmission circuit 200-7. The RF transmission circuit 200-7 feeds back food back data to the transmission station 100 as control information.

  Next, control bits transmitted by the receiving station 200 in the mobile communication system according to the present embodiment, that is, feedback data notified through the uplink control channel will be described with reference to FIGS.

  The feedback data generation unit 200-5 of the reception station 200 generates control information to be notified to the transmission station 100 based on the reception channel state measured by the reception channel state measurement unit 200-4.

  First, a case will be described where the reception channel states of the top N frequency blocks (N is an integer of N> 0), for example, SIR information and the ID of the frequency block are notified as control information in a good reception channel state.

  When the frequency characteristics of the reception channel state as shown in FIG. 5A are measured by the reception channel state measurement unit 200-4, the feedback data generation unit 200-5 of the reception station 200 uses the upper N as control information. The frequency block ID of each frequency block and its reception channel state are notified. For example, a case where N = 2 will be described. Since the upper two frequency blocks with good reception channel states have the frequency block IDs c and e, the IDs and the reception channel states of these IDs are notified as control information.

  Next, a case where the reception channel state of the frequency block is notified as control information at intervals of M (M is an integer of M> 0) will be described.

  When the frequency characteristics of the reception channel state as shown in FIG. 5B are measured by the reception channel state measurement unit 200-4, the feedback data generation unit 200-5 of the reception station 200 uses M pieces of control information as its control information. The frequency block ID and the reception channel state of the frequency block are notified at intervals (every M). In this case, the frequency block for notifying the reception channel state is specified using the downlink control channel. Moreover, you may make it change the frequency block to notify for every notification period. For example, a case where M = 3 will be described. For each of the three frequency blocks, the frequency block ID and the reception channel state of the frequency block are notified. For example, a, d, and g as frequency block IDs and reception channel states corresponding to these frequency blocks are notified as control information.

  Further, for example, based on a frequency block designated using a downlink control channel, the reception channel state of the designated frequency block may be notified as control information.

  Next, the case where the average of the reception channel states of all subcarriers and the difference in the reception channel state of each subcarrier with respect to this average are notified as control information will be described.

  When the frequency characteristics of the reception channel state as shown in FIG. 6A are measured by the reception channel state measurement unit 200-4, the feedback data generation unit 200-5 of the reception station 200 uses all sub-channels as its control information. The difference between the average reception channel state of carriers and the reception channel state of each subcarrier with respect to the average reception channel state is reported as control information.

  In this case, the average of the reception channel state, the IDs of the top N frequency blocks with good reception channel information, and the difference information thereof may be notified as control information. Further, the ID of the frequency block and the difference information thereof may be notified as control information at an average of the reception channel states and at intervals of M. In this case, the frequency block for notifying the reception channel state may be specified using the downlink control channel.

  Also, for example, based on the reception channel state of all subcarriers, a predetermined value, for example, the reception channel state of the best frequency block, the reception channel state of the worst frequency block, the reception channel state of the intermediate frequency block, etc. You may make it notify the difference with respect to the predetermined value of the receiving channel state of each subcarrier as control information.

  Further, for example, based on the frequency block designated using the downlink control channel, the average reception channel state and the difference information of the designated frequency block may be notified as control information.

  Next, a case will be described where frequency block IDs are reported as control information in the order of good reception channel conditions.

  When the frequency characteristics of the reception channel state as shown in FIG. 6B are measured by the reception channel state measurement unit 200-4, the feedback data generation unit 200-5 of the reception station 200 performs in the order of good reception channel state. The frequency block ID is notified as control information. For example, the frequency block ID is mapped to the uplink control channel and notified in the order of good reception channel state. For example, when the IDs of frequency blocks are arranged in the order of good reception channel state, the result is “e”, “c”, “d”, “f”, “b”, “g”, “a”. Notification is performed by mapping to the uplink control channel in order.

  In this case, the IDs of the N frequency blocks may be mapped to the uplink control channel and notified in order of good reception channel state.

  Further, the notification is not limited to the order in which the reception channels are good, but notification may be made in a predetermined order, for example, in the order of bad reception channels.

  Next, a case where the ID of a frequency block having a bad reception channel state is notified as control information will be described.

  When the frequency characteristics of the reception channel state as shown in FIG. 7 are measured by the reception channel state measurement unit 200-4, the feedback data generation unit 200-5 of the reception station 200 receives the ID of the frequency block having a bad reception channel state, For example, an ID of a frequency block that is not desired to be assigned is notified as control information. For example, a threshold value is determined in advance, and an ID of a frequency block whose reception channel state is worse than this threshold value is notified. By doing in this way, a user can be allocated to frequency blocks other than the notified frequency block. In this case, control information can be reduced when the reception channel states of frequency blocks other than the notified frequency block are substantially constant.

  In this case, the reception channel state of the top N frequency blocks with good reception channel state, the ID of the frequency block, and the ID of the lower P (P is an integer of P> 0) frequency block are notified. Anyway.

  Further, the average of the reception channel states of all frequency blocks, and the difference between the ID of the lower P frequency blocks and the average of the reception channel states may be notified.

  Further, the frequency block IDs may be notified in a predetermined order for the frequency blocks excluding the frequency block having a bad reception channel state.

  In the above-described embodiment, a plurality of generation methods have been described for the control bits generated in the feedback data generation unit 200-5 of the reception unit 200, but at least one is selected from the plurality of control bit generation methods. Therefore, a control bit estimation unit (not shown) for estimating the control bits to be transmitted is provided, and based on the control bit information amount estimated by the control bit estimation unit, the feedback data generation unit 200-5 transmits Control bits to be transmitted to the station 100, for example, control bits with a small amount of control bit information may be generated.

  Next, the reception channel state will be described with reference to FIG.

  Reception channel state measurement section 200-4 measures the reception channel state for each frequency block. A case where the reception SIR is used as the reception channel state will be described.

  The reception SIR measured by the reception channel state measurement unit 200-4 includes reception SIR or reception signal power (S) for each subcarrier averaged within the same frequency block in one radio frame time shown in FIG. ) And interference signal power (I), average value of received SIRs of all subcarriers in one radio frame time shown in FIG. 8B, within the same frequency block in one radio frame time shown in FIG. The reception SIR or S and I obtained by averaging the reception SIR or S and I for each subcarrier further time-averaged, and the average value of the reception SIR of all subcarriers in one radio frame time shown in FIG. Although there is an average received SIR and delay spread, any of them may be measured.

  In the reception SIR described above, the time average in the reception SIR shown in FIGS. 8C and 8D is sequentially updated using the forgetting factor.

  Further, FIG. 8 shows three radio frames and three frequency blocks, but the same applies to cases where there are 1, 2 and 3 or more radio frames and frequency blocks.

  Next, the operation of the transmission station 100 in the mobile communication system according to the present embodiment will be described. The transmitting station 100 allocates frequency blocks to users based on the control information fed back from the receiving station 200.

  Based on the control information fed back from the receiving station 200, the scheduler 100-3 creates a ranking table that ranks each user according to the priority described later. Next, scheduling is performed for each frequency block. For example, as shown in FIG. 9, the ranking is assigned to the three frequency blocks in order from the user with the highest ranking for each radio frame. In this case, each frequency block is independent.

  Here, the priority is an index for the allocation of each user's respective frequency blocks, and is a numerical value based on a reception channel state, a QoS (Quality of Service) request, and the like. In frequency scheduling, when the best frequency block is assigned to the same user in each frequency block, a user with many assigned frequency blocks and a user with few assigned frequency blocks are generated.

  For this reason, in the mobile communication system according to the present embodiment, the number of frequency blocks to be allocated to the same user in one radio frame is equal to or less than K in order to maintain the fairness of allocation among users (K is an integer of K> 0). Limit to.

  That is, the priority with respect to an unallocated frequency block of a user to whom K frequency blocks are allocated is deleted from the ranking table, and the unallocated frequency block is allocated to another user. However, when all the priorities are deleted from the ranking table of unassigned frequency blocks, the deleted priorities are validated and assigned to the highest ranking user.

Next, a method for determining the priority based on the control information notified from the receiving station 200 will be described. Priorities for each frequency block are determined according to the following rules.
(1) Reception channel state of each frequency block (2) Ratio of time average of reception channel state in each frequency block to reception channel state in radio frame of that frequency block (3) Reception channel in all subcarriers (frequency blocks) Ratio of average state and reception channel state in radio frame of allocation target frequency block (4) Time average of reception channel states in all subcarriers and reception in frequency block of allocation target of corresponding radio frame Ratio to channel state When the priority by the reception channel state, for example, the reception SIR is the same, the peak throughput can be improved by the frequency diversity effect by preferentially allocating the user having a large delay spread.

  In addition, when the priority of the reception channel state, for example, the reception SIR is the same, a user with a small delay spread is preferentially assigned. A user having a large delay spread has a small difference in average reception channel state, for example, average reception SIR, between frequency blocks, and therefore can allocate another frequency block.

  Next, a flow for creating a ranking table will be described with reference to FIG. 10, taking as an example the case where priority is determined according to the magnitude of the received SIR in each frequency block.

  The scheduler 100-3 of the transmitting station 100 determines a priority as an index for frequency block allocation of each user according to the size of the reception SIR in each frequency block, and creates a ranking table.

  Hereinafter, N is the total number of frequency blocks, I is the total number of receiving stations, SIR (i, n) is the received SIR for the frequency block n of the receiving station i, that is, feedback information (control information) from the receiving station 200, A {n } Is a set of received SIRs for frequency block n.

  First, the parameter n representing the frequency block n is set to an initial value (n = 0) (step S1001). Next, the parameter i representing the receiving station i is set to an initial value (i = 0) (step S1002).

  Next, it is determined whether or not the reception SIR (i, n) for the frequency block n of the receiving station i, that is, feedback information from the receiving station 200 has been received (step S1003). When SIR (i, n) is received (step S1003: Yes), SIR (i, n) in the set A {n} of received SIRs for frequency block n is overwritten. In this case, if there is no SIR (i, n) in A {n}, it is added (step S1004).

  On the other hand, when SIR (i, n) is not received (step S1003: No), SIR (i, n) is deleted from A {n}. In this case, if there is no SIR (i, n) in A {n}, nothing is done (step S1005).

  Next, 1 is added to the parameter i representing the receiving station i (i = i + 1) (step S1006).

  Next, it is determined whether or not the parameter i representing the receiving station i to which 1 has been added in step S1006 is less than the parameter I representing the total number of receiving stations I (step S1007).

  When the parameter i representing the receiving station i is less than the parameter I representing the total number of receiving stations I (i <I) (step S1007: Yes), the process returns to step S1003.

  On the other hand, when the parameter i representing the receiving station i is greater than or equal to the parameter I representing the total number of receiving stations I (step S1007: No), 1 is added to the parameter n representing the frequency block n (n = n + 1) ( Step S1008).

  Next, it is determined whether or not the parameter n representing the frequency block n to which 1 has been added in step S1008 is less than the parameter N representing the total frequency block number N (step S1009).

  When the parameter n representing the frequency block n is less than N representing the total frequency block number N (n <N) (step S1009: Yes), the process returns to step S1002.

  On the other hand, when the parameter n representing the frequency block n is not less than the parameter N representing all the frequency blocks N (step S1009: No), the parameter n representing the frequency block n is set to an initial value (n = 0) ( Step S1010).

  Next, the elements of received SIR set A {n} for frequency block n are rearranged in descending order of SIR (step S1011). Next, 1 is added to the parameter n representing the frequency block n (n = n + 1) (step S1012).

  Next, it is determined whether or not the parameter n representing the frequency block n to which 1 has been added in step S1012 is less than the parameter N representing the total frequency block number N (step S1013).

  When the parameter n representing the frequency block n is less than N representing the total frequency block number N (n <N) (step S1013: Yes), the process returns to step S1011. The processing from step S1011 to step S1013 is repeated until the parameter n representing the frequency block n becomes equal to or greater than the parameter N representing all the frequency blocks N.

  On the other hand, when the parameter n representing the frequency block n is not less than the parameter N representing all the frequency blocks N (step S1013: No), the process ends.

  Next, a frequency block allocation flow for allocating frequency blocks to users will be described. Here, a description will be given separately for a procedure for limiting the number of frequency blocks to be assigned to the same receiving station to K or less and a procedure for assigning frequency blocks.

  First, a procedure for limiting the number of frequency blocks allocated to the same receiving station to K or less will be described with reference to FIG.

  Based on the created ranking table, the scheduler 100-3 of the transmitting station 100 limits the number of frequency blocks allocated to the same receiving station to K or less and allocates frequency blocks.

  In the following, N is the total number of frequency blocks, user (n, r) is the receiving station ID information with priority r for the allocation of the frequency block n, and R (n) = {user (n, r)} is the frequency block n. Is a set of priority information for the allocation of.

  First, the parameter n representing the frequency block n is set to the initial value (n = 0), and the parameter r representing the priority order r is set to the initial value (r = 0) (step S1101). Next, 1 is added to the parameter r representing the priority order r (r = r + 1) (step S1102).

  Next, it is determined whether or not the receiving station ID information user (n, r) having the priority r for the allocation of the frequency block n exists in the set R (n) of the priority information for the allocation of the frequency block n. (Step S1103). If user (n, r) does not exist in R (n) (step S1103: No), the process returns to step S1102.

  On the other hand, if user (n, r) exists in R (n) (step S1103: Yes), the frequency block n is assigned to the receiving station user (n, r) (step S1104).

  Next, it is determined whether or not the number of frequency blocks assigned to the receiving station ID information user (n, r) with the priority ranking of the allocation of the frequency block n is K (step S1105). When the number of frequency blocks allocated to user (n, r) is K (step S1105: Yes), a value obtained by adding 1 to the parameter n representing the frequency block n is set to m (m = n + 1) (step S1108).

  Next, the priority information of the receiving station and user (n, r) is deleted from the priority order information set R (m) for the allocation of the frequency block m (step S1109). Next, 1 is added to the parameter m representing the frequency block m (m = m + 1) (step S1110).

  Next, it is determined whether or not the parameter m representing the frequency block m to which 1 has been added in step S1110 is less than the parameter N representing the total frequency block number N (step S1111).

  When the parameter m representing the frequency m is less than the parameter N representing the total frequency block number N (m <N) (step S1111: Yes), the process returns to step S1109.

  On the other hand, when the parameter m representing the frequency block m is not less than the parameter N representing all the frequency blocks N (step S1111: No) and when the number of frequency blocks assigned to user (n, r) is not K in step S1105. (Step S1105: No), 1 is added to the parameter n representing the frequency block n (n = n + 1) (step S1106).

  Next, it is determined whether or not the parameter n representing the frequency block n to which 1 has been added in step S1106 is less than the parameter N representing the total frequency block number N (step S1107).

  When the parameter n representing the frequency block n is less than the parameter N representing the total frequency block number N (n <N) (step S1107: Yes), the process returns to step S1102. The processing from step S1102 to step S1107 is repeated until the parameter n representing the frequency block n becomes equal to or greater than the parameter N representing all the frequency blocks N.

  On the other hand, when the parameter n representing the frequency block n is not less than the parameter N representing all the frequency blocks N (step S1107: No), the process ends.

  Next, a procedure for assigning frequency blocks will be described with reference to FIGS.

  The scheduler 100-3 of the transmitting station 100 allocates users to frequency blocks based on the created ranking table.

  First, as shown in FIG. 12, a table is created in which the priorities, which are indices for frequency block allocation, of each user are ranked. Next, frequency blocks are assigned from the top of the created ranking table, and the priority of the already assigned frequency block as the target frequency block is deleted from the table.

  For example, a description will be given with reference to a ranking table shown in FIG. FIG. 12 is an example of a ranking table. For priorities 1 to 5, priorities u, v, w, x, z, user IDs 3, 2, 5, 3, 2, target blocks D, D, A, B and A are associated with each other.

  First, the frequency block D is assigned to the user 3 according to the priority order, and the priority for the frequency block D is deleted from the ranking table. In this case, the user 2 whose priority is 2 is deleted from the ranking table. Next, the remaining frequency blocks are allocated. In this case, the frequency block A having a priority of 3 is assigned to the user 5, and the priority for the frequency block A is deleted from the ranking table. In this case, the user 2 with the priority order 5 is deleted from the ranking table. Thereafter, the same processing is repeated to assign a frequency block to each user.

  By doing in this way, the frequency block with the best reception channel state can always be assigned to each user.

  Next, a frequency block allocation flow for allocating frequency blocks to users will be described with reference to FIG. Here, a case will be described as an example where the priority is determined according to the size of the reception SIR in each frequency block.

  Hereinafter, SIR (i, n) is a reception SIR for the frequency block n of the receiving station i, that is, feedback information (control information) from the receiving station i, I is the total number of receiving stations, N is the total number of frequency blocks, and R is the frequency The priority of received SIR information for a block, User (R) is a receiving station ID having SIR information of priority R, and Block (R) is a frequency block ID targeted by SIR information of priority R.

  First, priorities are assigned to SIR (i, n) (0 <i <I, 0 <n <N) representing the received SIR for the frequency block n of the receiving station i in descending order (step S1301).

  Next, the parameter R representing the priority order R of the SIR information for the frequency block n is set to an initial value (R = 0), and the parameter nn representing the frequency block nn is set to an initial value (nn = 0) (step 0). S1302).

  Next, it is determined whether or not there is parameter R information indicating the priority order R of the SIR information for the frequency block (step S1303).

  If there is information on the parameter R indicating the priority R of the SIR information for the frequency block (step S1303: Yes), the priority R is set in the parameter User (R) indicating the receiving station ID having the SIR information of the priority R. A parameter Block (R) representing the frequency block ID targeted by the SIR information is assigned (step S1304).

  Next, 1 is added to the parameter nn representing the frequency block nn (nn = nn + 1) (step S1305). Next, it is determined whether or not the parameter nn representing the frequency block nn added with 1 in step S1305 is less than the parameter N representing the total frequency block number N (step S1306).

  If the parameter nn representing the frequency block nn is not less than the parameter N representing the total number N of frequency blocks (step S1306: No), the process ends.

  On the other hand, when the parameter nn representing the frequency block nn is less than the parameter N representing the total frequency block number N (nn <N) (step S1306: Yes), the parameter representing the priority R of the received SIR information for the frequency block. A value obtained by adding 1 to R is set as r (r = R + 1) (step S1307).

  Next, the parameter r representing the priority order of the SIR information for the frequency block obtained in step S1307 is less than the product (I × N) of the parameter I representing the total number of receiving stations and the parameter N representing the total frequency block number N. It is determined whether or not there is (step S1308).

  When the parameter r representing the priority order of the SIR information for the frequency block is less than the product of the parameter I representing the total number of receiving stations and the parameter N representing the total frequency block number N (r <I × N) (step S1308). : Yes), whether the parameter Block (r) indicating the frequency block ID targeted by the SIR information of priority r is equal to the parameter Block (R) representing the frequency block ID targeted by the SIR information of priority R Is determined (step S1309).

  When the parameter Block (r) representing the frequency block ID targeted by the SIR information of priority r is equal to the parameter Block (R) representing the frequency block ID targeted by the SIR information of priority R (Block ( r) = Block (R)) (step S1309: YES), the process returns to step S1307.

  On the other hand, when the parameter Block (r) representing the frequency block ID targeted by the SIR information of priority r is not equal to the parameter Block (R) representing the frequency block ID targeted by the SIR information of priority R (Step S1309: No), information of priority r, that is, parameter User (r) representing a receiving station ID having received SIR information of priority r, and frequency block ID targeted by received SIR information of priority r The represented parameter Block (r) is deleted (step S1310), and the process returns to step S1307.

  On the other hand, when the parameter r representing the priority order of the SIR information for the frequency block is not less than the product (I × N) of the parameter I representing the total number of receiving stations and the parameter N representing the total frequency block number N in step S1308 ( In step S1308: No) and in step S1303, if there is no parameter R information indicating the priority order R of the SIR information for the frequency block (step S1303: No), the priority order R of the SIR information for the frequency block is indicated. 1 is added to the parameter R (R = R + 1) (step S1311).

  Next, the parameter R representing the priority R of the received SIR information for the frequency block to which 1 is added in step S1311, is the product of the parameter I representing the total number of receiving stations and the parameter N representing the total frequency block number N (I × N) whether it is less than or not is determined (step S1312).

  When the parameter R representing the priority order R of the received SIR information for the frequency block is less than the product of the parameter I representing the total number of receiving stations and the parameter N representing the total frequency block number N (R <I × N) (step S1312: Yes), the process ends.

  On the other hand, when the parameter R representing the priority order of the received SIR information for the frequency block is not less than the product (I × N) of the parameter I representing the total number of receiving stations and the parameter N representing the total frequency block number N (step S1312: No). ), The process returns to step S1303.

  Next, a mobile communication system according to a second embodiment of the present invention is described.

  In the embodiment described above, the case where the transmitting station 100 assigns all frequency blocks to all users (receiving stations) based on the control information fed back from the receiving station 200 has been described.

  The transmitting station 100 according to the present embodiment allocates users (receiving stations) to frequency blocks in a fixed manner in advance, and between users allocated to the same frequency block, according to the channel fluctuation of each user in the frequency block, Perform time domain scheduling.

  For example, as shown in FIG. 14, the user is distributed to one or a plurality of schedulers that perform scheduling for each frequency block. For example, User1 and User4 are allocated to the same scheduler, User2 and User5 are allocated to the same scheduler, and User3 and User6 are allocated to the same scheduler. The scheduler to which User1 and User4 are assigned performs scheduling between User1 and User4, the scheduler to which User2 and User5 are assigned performs scheduling between User2 and User5, and the scheduler to which User3 and User6 are assigned is User3. And user 6 are scheduled.

  In this way, the receiving station 200 only needs to transmit uplink control information in the frequency block corresponding to the distributed scheduler, for example, information indicating the reception channel state, and thus the receiving station 200 transmits to the transmitting station 100. The amount of uplink control information can be reduced.

  The transmitting station 100 according to the present embodiment will be described with reference to FIG.

  The transmission station 100 according to the present embodiment includes a user assignment unit 100 connected to the packet selection unit 100-5, the buffer management unit 100-6, and a scheduler 100-13 described later, in addition to the transmission station described with reference to FIG. -12, one or a plurality of schedulers 100-13 connected as a scheduler 100-3 to a demodulator / decoder 100-2 and a buffer manager 100-6, and a PDU generator 100-7 as a transmission buffer 100-8 1 or a plurality of transmission buffers 100-14 connected to each other, and a selector 100-15 connected to each scheduler and each transmission buffer as a selector 100-9. Each selector 100-15 is connected to the encoder / modulator 100-10. In this embodiment, a case where a scheduler is provided for each frequency block, that is, a case where the frequency block and the scheduler correspond one-to-one will be described.

  The user allocation unit 100-12 determines a frequency block to be allocated to each user, and inputs information indicating the destination user and the frequency block allocated to the user to the packet selection unit 100-5 and the buffer management unit 100-6. In addition, the user allocation unit 100-12 inputs information indicating the destination user to the scheduler 100-13 corresponding to the frequency block to be allocated.

  For example, the user allocation unit 100-12 allocates a new user to a frequency block with a small number of allocated users.

  Further, for example, the user allocation unit 100-12 may allocate a new user to a frequency block with a small amount of data waiting for transmission. In this case, the user allocation unit 100-12 refers to the queue state of each transmission buffer 100-14 managed by the buffer management unit 100-6, and allocates a new user to a frequency block with a small amount of transmission waiting data.

  Further, for example, the type of traffic handled for each frequency block may be different, and a new user may be assigned to the frequency block according to the type of traffic to be transmitted. Further, for example, a new user may be assigned to a frequency block in response to a delay request. Further, for example, a new user may be assigned to the frequency block according to the data size to be transmitted.

  Here, although the case where one frequency block is allocated to one user has been described, for example, the user allocation unit 100-12 may allocate a plurality of frequency blocks to one user. In this case, the user allocation unit 100-12 inputs information indicating the destination user and the frequency block allocated to the user to the packet selection unit 100-5 and the buffer management unit 100-6.

  The packet sorting unit 100-5 sorts the input IP packet based on the information indicating the destination user notified by the user allocation unit 100-12 and the frequency block to be assigned to the user, and the sorted packet Each time, the data is input to the PDU generation unit 100-7. The PDU generation unit 100-7 converts the input packet into a PDU and inputs the packet to each transmission buffer 100-14 provided corresponding to the frequency block, for example.

  Each transmission buffer 100-14 has an independent queue for each destination (receiving station) from the input PDU based on the destination address input by the buffer management unit 100-6 and the memory address of the corresponding queue. And the status of each queue is notified to the buffer management unit 100-6.

  The selector 100-15 is provided for each frequency block, extracts data from the queue corresponding to the scheduler 100-13, and inputs the data to the corresponding encoding / modulation unit 100-10. The scheduler 100-13 assigns each user based on the notified uplink control information of each receiving station, for example, the downlink reception channel state of the frequency block assigned to the receiving station, the packet header information, and the state of each queue. An index (priority) for a given frequency block is obtained, and time domain scheduling is performed based on the index.

  For example, each scheduler 100-13 performs processing using a different scheduling algorithm for each corresponding frequency block. For example, scheduling is performed based on the FIFO for frequency blocks that handle traffic with severe delay requirements, and based on the reception channel for frequency blocks that handle traffic with moderate delay requirements.

  The encoding / modulation unit 100-10 performs encoding / modulation processing on the input data, and the encoded / modulated processing data is input to the RF transmission circuit 100-11. The RF transmission circuit 100-11 transmits the input encoded / modulated data.

  In the transmission station 100 described in the present embodiment, the case has been described in which the PDU generation unit 100-7 divides the input packet into a PDU and then stores the PDU in the transmission buffer 100-14. One or a plurality of PDU generation units are arranged between the selector 100-15 and the encoding / modulation unit 100-10, and the data to be transmitted in each frequency block is extracted from the designated queue by the selector 100-15. After that, the extracted data may be divided into PDUs.

  Next, the receiving station according to the present embodiment will be described.

  The receiving station according to this embodiment has the same configuration as the receiving station described with reference to FIG. The feedback data generation unit 100-5 indicates the reception channel state in the allocated frequency block based on the information indicating the allocated frequency block notified in advance from the transmitting station 100 and the received reception channel state measurement value. Feedback data (control information) is generated, and the generated feedback data is input to the encoding / modulation unit 200-6.

  Further, the reception channel state measurement unit 100-4 measures the reception state in the allocated frequency block based on the information indicating the allocated frequency block notified in advance from the transmitting station 100, and generates the feedback data as a result of the measurement. The input may be made to the section 200-5.

  By doing so, the amount of information fed back to the transmitting station 100 can be reduced.

  In the present embodiment, the case where a plurality of schedulers 100-13, a plurality of transmission buffers 100-14, and a plurality of selectors 100-15 are provided has been described, but one scheduler 100-13, one transmission buffer 100-14 and one are provided. One selector may be provided, and processing may be performed serially or may be performed by software.

  Next, the operation of the transmission station 100 in the mobile communication system according to the present embodiment will be described with reference to FIG. The transmitting station 100 transmits information indicating the frequency block assigned to each receiving station. Further, based on the control information fed back from the receiving station 200, time domain scheduling is performed for each receiving station in the allocated frequency block.

  First, in the user allocation unit 100-12, a process of distributing users to frequency blocks is performed (step S1602).

  Next, the user allocation unit 100-12 notifies each user of information indicating the allocated frequency block (step S1604).

  Next, the scheduler 100-13 determines whether or not control information is fed back from the receiving station 200 (step S1606).

  When control information is fed back from the receiving station 200 (step S1606: YES), the scheduler 100-13 obtains an index (priority) for the frequency block assigned to each receiving station (step S1608).

  On the other hand, when control information is not fed back from the receiving station 200 (step S1606: NO), the process returns to step S1606.

  Next, the scheduler 100-13 performs time domain scheduling based on the priority (step S1610).

  Next, a mobile communication system according to a third embodiment of the present invention is described with reference to FIG.

  The transmitting station 100 according to the present embodiment is configured by a single scheduler 100-16 as the scheduler 100-13 in the transmitting station 100 according to the second embodiment described with reference to FIG.

  The scheduler 100-16 manages, for example, a plurality of frequency blocks as a group (set). For example, a plurality of frequency blocks may be managed as a group according to the type of traffic to be handled. In addition, the scheduler assigns each user based on the notified uplink control information of each receiving station, for example, the downlink reception channel state of the frequency block assigned to the receiving station, packet header information, and the state of each queue. An index (priority) for each frequency block is obtained, and scheduling in the time domain and the frequency domain is performed based on the index. For example, scheduler 100-16 specifies one or more queues.

  The selector 100-15 extracts data from the queue designated by the scheduler 100-13 and inputs the data to the encoding / modulation unit 100-10 corresponding to the designated frequency block.

  The user assigning unit 100-12 determines a group of frequency blocks to be assigned to each user, and sets information indicating the destination user and the group of frequency blocks to be assigned to the user to the packet selecting unit 100-5 and the buffer managing unit 100-6. To enter. Also, the user allocation unit 100-12 inputs information indicating the destination user and the group of frequency blocks allocated to the user to the scheduler 100-16. For example, the user allocation unit 100-12 allocates a new user to a group of frequency blocks with a small number of allocated users. Further, for example, a plurality of frequency blocks may be designated as the frequency block to be allocated.

  Similarly to the second embodiment, for example, the user assigning unit 100-12 may assign a new user to a group of frequency blocks with less transmission waiting data. Further, for example, the type of traffic handled for each frequency block may be different, and a new user may be assigned to a group of frequency blocks according to the type of traffic to be transmitted. Further, for example, a new user may be assigned to a group of frequency blocks in response to a delay request. For example, a new user may be assigned to a group of frequency blocks according to the data size to be transmitted.

  In the transmission station 100 described in the present embodiment, the case has been described in which the PDU generation unit 100-7 divides the input packet into a PDU and then stores the PDU in the transmission buffer 100-14. One or a plurality of PDU generation units are arranged between the selector 100-15 and the encoding / modulation unit 100-10, and the data to be transmitted in each frequency block is extracted from the designated queue by the selector 100-15. After that, the extracted data may be divided into PDUs.

  Next, the receiving station according to the present embodiment will be described.

  Since the receiving station according to the present embodiment has the same configuration as the receiving station described in the second embodiment, the description thereof is omitted.

  Next, the operation of the transmission station 100 in the mobile communication system according to the present embodiment will be described with reference to FIG. The transmitting station 100 transmits information indicating the frequency block assigned to each receiving station. Further, based on the control information fed back from the receiving station 200, the transmitting station 100 performs time domain and frequency domain scheduling for each receiving station in the allocated frequency block.

  Here, a case will be described as an example where a plurality of frequency blocks are managed as a group (set) and the priority is determined according to the size of the reception SIR in each frequency block.

  Hereinafter, SIR (i, n) is a reception SIR for the frequency block n of the receiving station i, that is, feedback information (control information) from the receiving station i, and I is the total number of receiving stations assigned to a group (set) of frequency blocks. , N is the total number of frequency blocks in the group (set) of frequency blocks, R is the priority of received SIR information for the frequency block, User (R) is a receiving station ID having SIR information of priority R, and Block (R) is The SIR information with priority R is the target frequency block ID.

  First, a frequency block to be assigned to each user is determined (step S1802).

  Next, SIR (i, n) (0 <i <I, 0 <n <N) representing the received SIR for the frequency block n of the receiving station i is prioritized in descending order (step S1804). .

  Next, the parameter R representing the priority order R of the SIR information for the frequency block n is set to an initial value (R = 0), and the parameter nn representing the frequency block nn is set to an initial value (nn = 0) (step 0). S1806).

  Next, it is determined whether or not there is parameter R information indicating the priority order R of the SIR information for the frequency block (step S1808).

  If there is information on the parameter R indicating the priority R of the SIR information for the frequency block (step S1808: Yes), the priority R is set in the parameter User (R) indicating the receiving station ID having the SIR information of the priority R. The parameter Block (R) representing the frequency block ID targeted by the SIR information is assigned (step S1810).

  Next, 1 is added to the parameter nn representing the frequency block nn (nn = nn + 1) (step S1812). Next, it is determined whether or not the parameter nn representing the frequency block nn added with 1 in step S1812 is less than the parameter N representing the total number N of frequency blocks in the group of frequency blocks (step S1814).

  If the parameter nn representing the frequency block nn is not less than the parameter N representing the total number N of frequency blocks in the group of frequency blocks (step S1814: No), the process ends.

  On the other hand, when the parameter nn representing the frequency block nn is less than the parameter N representing the total number N of frequency blocks in the group of frequency blocks (nn <N) (step S1814: Yes), the priority of the received SIR information for the frequency block A value obtained by adding 1 to the parameter R representing the rank R is set as r (r = R + 1) (step S1816).

  Next, the parameter r indicating the priority of the SIR information for the frequency block obtained in step S1816 is the parameter I indicating the total number of receiving stations assigned to the frequency block group and the total frequency block number N of the frequency block group. It is determined whether it is less than the product (I × N) with the parameter N to be represented (step S1818).

  The parameter r representing the priority of the SIR information for the frequency block is less than the product of the parameter I representing the total number of receiving stations assigned to the frequency block group and the parameter N representing the total frequency block number N in the frequency block group. In this case (r <I × N) (step S1818: Yes), the parameter Block (r) indicating the frequency block ID targeted by the SIR information of priority r and the frequency block targeted by the SIR information of priority R It is determined whether or not the parameter Block (R) representing the ID is equal (step S1820).

  When the parameter Block (r) representing the frequency block ID targeted by the SIR information of priority r is equal to the parameter Block (R) representing the frequency block ID targeted by the SIR information of priority R (Block ( r) = Block (R)) (step S1820: Yes), the process returns to step S1816.

  On the other hand, when the parameter Block (r) representing the frequency block ID targeted by the SIR information of priority r is not equal to the parameter Block (R) representing the frequency block ID targeted by the SIR information of priority R (Step S1820: No), information of priority r, that is, parameter User (r) indicating a receiving station ID having received SIR information of priority r, and frequency block ID targeted by received SIR information of priority r The represented parameter Block (r) is deleted (step S1822), and the process returns to step S1816.

  On the other hand, in step S1818, the parameter r representing the priority order of the SIR information for the frequency block is a parameter I representing the total number of receiving stations assigned to the frequency block group and a parameter representing the total frequency block number N in the frequency block group. If it is not less than the product (I × N) with N (step S1818: No), and if there is no parameter R information indicating the priority R of the SIR information for the frequency block in step S1808 (step S1808: No) ), 1 is added to the parameter R indicating the priority R of the SIR information for the frequency block (R = R + 1) (step S1824).

  Next, the parameter R representing the priority R of the received SIR information for the frequency block to which 1 has been added in step S1824 is the parameter I representing the total number of receiving stations assigned to the frequency block group and the total frequency of the frequency block group. It is determined whether it is less than the product (I × N) with the parameter N representing the number of blocks N (step S1826).

  The parameter R representing the priority R of the received SIR information for the frequency block is the product of the parameter I representing the total number of receiving stations assigned to the frequency block group and the parameter N representing the total frequency block number N in the frequency block group. If it is less than (R <I × N) (step S1826: Yes), the process ends.

  On the other hand, the parameter R representing the priority order of the received SIR information for the frequency block is the product of the parameter I representing the total number of receiving stations assigned to the frequency block group and the parameter N representing the total frequency block number N in the frequency block group. When it is not less than (I × N) (step S1826: No), the process returns to step S1808.

  In this embodiment, the case where a plurality of frequencies are managed as a group has been described. However, the scheduler may arbitrarily select a frequency block.

  In the above-described embodiment, the case has been described in which the frequency block in which the reception channel state is notified from the reception station 200 to the transmission station 100 is allocated to the user. Here, a case where a frequency block to which a reception channel state from the receiving station 200 is not notified is assigned to a user will be described with reference to FIGS. 19 and 20.

  A case will be described where only the reception channel states of some frequency blocks are notified from the receiving station 200 and there are frequency blocks for which the reception channel states are not notified.

  First, a case where priority is given to a frequency block for which a reception channel state has been notified in the past will be described.

  For example, in the frequency characteristics of the reception channel state shown in FIG. 19A, a case where the reception channel state for the frequency block E is notified and the reception channel state for the frequency blocks C and F is not notified will be described.

The frequency block F, the reception channel state before one radio frame when being notified to the notified delta ₁ lower than the channel state had values as current reception channel state. For the frequency block C, when the reception channel state is notified two radio frames ago, a value lower by Δ ₂ than the notified channel state is set as the current reception channel state.

  In these cases, priority is given to a frequency block whose notified time is later. For example, for a certain frequency block, when the reception channel state is notified two radio frames before and one radio frame before, the current radio channel is determined based on the reception channel state one radio frame before the notified time Determine the state.

  Next, a case where priority is given to a frequency block adjacent to a frequency block in which the reception channel state is notified, that is, a case where the priority of an adjacent block is increased will be described.

  For example, in the frequency characteristics of the reception channel state shown in FIG. 19B, a case where the reception channel state for the frequency block E is notified and the frequency blocks D and F adjacent to the frequency block E are not notified will be described. In this case, since it is estimated that the correlation between the frequency block E having a good frequency channel state and the frequency blocks D and F is high, the priority of the frequency blocks D and F is increased. This method can be applied when the variation of the reception channel characteristic is moderate.

  Next, a case will be described where priority is given to frequency blocks that are separated by L blocks (L is an integer of L> 0) from the frequency block for which the reception channel state is notified.

  For example, in the frequency characteristics of the reception channel state shown in FIG. 20 (a), when the reception channel state for the frequency block B is notified, L blocks away from the frequency block B, for example, frequency blocks E separated by three. Increase the priority for. This method can be applied when the reception channel characteristics fluctuate drastically and the same frequency block is assigned.

  Next, a case will be described in which priority is given to frequency blocks that are separated by L or more from frequency blocks with poor reception channel conditions.

  For example, in the frequency characteristic of the reception channel state shown in FIG. 20B, when the reception channel state for the frequency block B is notified, a frequency block that is more than L away from the frequency block B, for example, a frequency block that is three away Increase the priority for E. By using this method, a frequency block that is far from a frequency block with a bad reception channel state is considered to have a better reception channel state than a frequency block with a bad reception channel state, and a frequency channel with a good reception channel state is assigned. be able to.

  Further, the above-described method may be switched to assign a priority frequency channel. For example, a determination unit (not shown) for determining whether the priority obtained by using any method from the frequency characteristics of the reception channel state can improve the throughput of the entire system is provided. Based on the determination of the determination unit To determine the priority.

  Next, system bandwidth blocking will be described separately when adjacent subcarriers are grouped together, when subcarriers separated by a certain number of carriers are blocked, and when multiple blocks are grouped together. . The transmitting station 100 further blocks the subcarriers (frequency blocks) and transmits them.

  First, the case where adjacent subcarriers are collectively blocked will be described.

  As shown in FIG. 21A, adjacent subcarriers are collectively blocked. For example, adjacent subcarriers are grouped into four blocks. By doing so, the effect of frequency scheduling can be increased when the delay spread is small.

  Next, a case where subcarriers separated by a certain number of carriers are blocked will be described. As shown in FIG. 21B, subcarriers separated by a certain number of carriers are blocked. For example, subcarriers separated by four carriers are grouped into blocks. By doing so, the effect of frequency interleaving can be increased when the delay spread is large.

  Next, a case where a plurality of blocks are grouped together will be described. As shown in FIGS. 21 (c) and 21 (d), each receiving station notifies only the reception channel state of some blocks. That is, when “the number of receiving stations × the number of frequency blocks for notifying the reception channel state” is smaller than the number of blocks, several frequency blocks are combined into one block. By doing so, it is possible to prevent a frequency block without a receiving station notifying the reception channel state from occurring.

  Next, regarding the use of the code area, when providing a code channel to be frequency-blocked and a code channel not to be frequency-blocked, the remaining code channels of the frequency block to which the user is assigned are assigned to another user. This will be described with reference to FIG.

  First, a case where a code channel that performs frequency blocking and a code channel that does not perform frequency blocking are provided will be described.

  As shown in FIG. 22A, a frequency domain and a code domain are considered, and a code channel that is frequency-blocked and a code channel that is not frequency-blocked are provided for the frequency domain.

  The code channel to be frequency-blocked and the code channel not to be frequency-blocked are used according to traffic. For example, a code channel that is not frequency-blocked is a user who cannot expect a gain due to frequency scheduling, which is highly important and traffic with almost no error, such as control traffic, high-priority traffic such as RT (Real-Time) traffic, etc. Use for.

  Further, the number of code channels to be blocked may be variable in accordance with the traffic volume using code channels that are not to be blocked.

  Next, a case where the remaining code channel of the frequency block to which the user is allocated is allocated to another user will be described.

  As shown in FIG. 22B, a certain code channel is assigned to a user who has the highest priority in the frequency block, and the remaining code channels are assigned to users who have a second highest priority. That is, a plurality of code channels that are frequency-blocked are assigned to data transmission to a plurality of receiving stations.

  Further, the frequency band may be divided for each transmission slot.

  For example, as shown in FIG. 23, transmission slots that are not frequency-transmitted and non-transmission slots are provided. For example, for frequency blocks that are not to be blocked, traffic that is highly important and hardly tolerates errors, such as control traffic, high-priority traffic, traffic that cannot be delayed, such as RT (real time) traffic, etc. Used for users who cannot expect gains due to frequency scheduling. Further, the ratio of transmission slots to be blocked may be made variable according to the traffic volume.

  In the above-described embodiment, an example in which a user is allocated to each frequency block has been described. However, radio resources may be allocated.

  The following items are further disclosed regarding the embodiment including the above examples.

(1) A receiving station in a mobile communication system that receives a plurality of subcarriers transmitted from a transmitting station:
Receiving channel state measuring means for measuring a receiving channel state for each frequency block obtained by dividing the frequency band;
Control information generating means for generating control information indicating the reception channel state of the frequency block to be notified to the transmitting station based on the measured reception channel state;
Is provided.

  With this configuration, it is possible to generate control information indicating the reception channel state of the frequency block to be notified to the transmission station based on the measured reception channel state.

(2) In the receiving station described in (1):
The reception channel state measuring means measures one reception channel state of a frequency block assigned to the own mobile communication system and a frequency block assigned to the own reception station.

(3) In the receiving station described in (1) or (2):
The control information generation means, based on the measured reception channel state, the reception channel state of the frequency block that satisfies a predetermined condition, the ID of the frequency block that satisfies the predetermined condition, the ID of the specified frequency block, and the Control information for any one of the reception channel state corresponding to the ID of the designated frequency block, the average value of the measured reception channel state, and the difference between the average value and the measured reception channel state Generate as

(4) In the receiving station according to any one of (1) to (3):
The control information generating unit generates, as control information, a predetermined value determined based on the measured reception channel state and a difference between the predetermined value and the measured reception channel state.

(5) A transmitting station in a mobile communication system that transmits a plurality of subcarriers to a receiving station:
A radio resource is allocated to each frequency block obtained by dividing the frequency band allocated to the mobile communication system,
An allocation for allocating the radio resource for each frequency block based on the index is obtained based on the control information indicating the reception channel state of the frequency block notified from the receiving station. means;
Is provided.

  With this configuration, an index for radio resource allocation for each frequency block can be obtained based on the control information notified from the receiving station, and the radio resource can be allocated to each frequency block.

(6) In the transmitting station described in (5):
Distribution means for allocating receiving stations to frequency blocks;
With
The assigning means assigns radio resources of frequency blocks to the assigned receiving stations.

(7) In the transmitting station described in (6):
The allocating means divides a receiving station into a frequency block based on at least one of the number of receiving stations allocated in each frequency block, transmission waiting data, type of traffic to be transmitted, delay request, and data size to be transmitted. Distribute.

(8) In the transmitting station described in (6) or (7):
The allocating unit uses a different algorithm when allocating radio resources for each frequency block.

(9) In the transmitting station according to any one of (5) to (8):
The allocating means includes a reception channel state of each frequency block, a ratio between a time average of the reception channel state in each frequency block and a reception channel state in a radio frame of the frequency block, an average of reception channel states in all frequency blocks and an allocation target. An index based on at least one of a ratio of the frequency block of the frequency block to the reception channel state in the radio frame and a ratio of the average time of the reception channel state of all frequency blocks to the reception channel state of the frequency block to be allocated Ask.

(10) In the transmitting station described in (9):
The allocating unit uses a frequency block for which the reception channel state is notified and a value obtained based on the reception channel state as the reception channel state of the frequency block for which the reception channel state is not notified.

(11) In the transmitting station according to any one of (5) to (10):
The allocating unit controls the number of frequency blocks allocated to the radio resource per receiving station.

(12) In the transmitting station according to any one of (5) to (11):
The assigning means blocks a plurality of frequency blocks.

(13) In the transmitting station according to any one of (5) to (12):
Means for transmitting each frequency block;
Is provided.

(14) In the transmitting station described in (13):
The transmission means transmits using a code channel that is frequency-blocked and a code channel that is not frequency-blocked.

(15) In the transmitting station described in (14):
The transmission means allocates a plurality of frequency-blocked code channels to data transmission to a plurality of receiving stations.

(16) In the transmitting station described in (13):
The transmission means divides the frequency band for each transmission slot.

(17) In the transmitting station according to any one of (5) to (16):
A notification means for notifying the receiving station of information indicating the distributed radio resource;
Is provided.

(18) A mobile communication system comprising a transmitting station and a receiving station that receives a plurality of subcarriers transmitted from the transmitting station:
The receiving station is
Receiving channel state measuring means for measuring a receiving channel state for each frequency block obtained by dividing the frequency band;
Control information generating means for generating control information indicating the reception channel state of the frequency block to be notified to the transmitting station based on the measured reception channel state;
With
The transmitting station is
An allocation unit that obtains an index for radio resource allocation for each frequency block based on control information indicating the reception channel state of the frequency block notified from the receiving station, and allocates radio resources for each frequency block based on the index ;
Is provided.

  With this configuration, the receiving station can generate control information indicating the receiving channel state of the frequency block to be notified to the transmitting station based on the measured receiving channel state. An index for radio resource allocation for each frequency block can be obtained based on the control information notified from, and the radio resource can be allocated for each frequency block.

(19) In the mobile communication system according to (18):
The reception channel state measuring means measures one reception channel state of a frequency block assigned to the own mobile communication system and a frequency block assigned to the own reception station.

(20) A frequency block allocation method in a mobile communication system comprising a transmitting station and a receiving station that receives a plurality of subcarriers transmitted from the transmitting station:
Measuring a reception channel state for each frequency block obtained by dividing the frequency band;
Generating control information indicating a reception channel state of the frequency block to be notified based on the measured reception channel state;
Obtaining an index for allocation of radio resources of each frequency block based on the control information, and allocating radio resources to each frequency block based on the index;
Have

  In this way, the transmitting station can obtain an index for radio resource allocation for each frequency block based on the control information notified from the receiving station, and can allocate the radio resource to each frequency block.

(21) In the frequency block allocation method according to (20):
The measuring step includes a step of measuring a reception channel state of one of the frequency block allocated to the mobile communication system and the frequency block allocated to the local reception station.

  The receiving station, transmitting station, mobile communication system, and frequency block allocation method according to the present invention can be applied to a mobile communication system that divides the entire system band into a plurality of frequency blocks and allocates radio resources for each block.

100 transmitting station 200 receiving station

Claims (12)

A receiving unit for receiving information indicating a frequency block distributed by the transmitting station ;
A reception channel state measurement unit for measuring a reception channel state of the frequency block based on information indicating the frequency block received by the reception unit ;
A control information generation unit that generates control information indicating a reception channel state of the frequency block to be notified to the transmission station based on the reception channel state measured by the reception channel state measurement unit;
Wherein the transmitting station, the receiving station, characterized in that to obtain Bei and a notification unit configured to notify the control information generated by the control information generating unit. A distribution unit that distributes a plurality of receiving stations to a frequency block obtained by dividing the frequency band ;
A notification unit for notifying the plurality of receiving stations of information indicating the frequency blocks distributed by the distribution unit;
It said plurality of based on the control information indicating the reception channel state notified the frequency blocks from the receiving station obtains an index related to the allocation of radio resources in the frequency block for each of the receiving stations, based on the indicator, the time domain And a scheduler for performing scheduling . The distribution unit, the number of receiving stations distributed to each frequency block, transmission waiting data, the type of traffic to be transmitted, based on one even without least data size delay requirement and sending, the receiving station to the frequency blocks The transmitting station according to claim 2, wherein the transmitting station is assigned. 4. The transmission station according to claim 2, wherein the scheduler uses a different algorithm for each frequency block when performing scheduling in the time domain . The scheduler includes a reception channel state of each frequency block, a ratio between a time average of the reception channel state in each frequency block and a reception channel state in a radio frame of the frequency block, an average of reception channel states in all frequency blocks, and an allocation target. the ratio of the reception channel state in the radio frame frequency blocks, and an indication based on one even without less of the ratio of the reception channel state in the average of the time average allocation object frequency blocks of the reception channel state in all the frequency blocks 5. The transmitting station according to claim 2, wherein the transmitting station is obtained. 6. The scheduler according to claim 5, wherein a frequency block whose reception channel state is notified and a value obtained based on the reception channel state are used as a reception channel state of a frequency block whose reception channel state is not notified. The listed transmitting station. The scheduler transmitting station according to any one of claims 2 to 6, characterized in that for controlling the number of frequency blocks to be allocated to the receiving station. Using a second code channel without blocking the first code channel and a plurality of frequency blocks of frequency blocks of multiple, to claims 2, characterized in that it comprises a transmission section that transmit 7 The transmitting station according to any one of the above. The transmitting station according to claim 8, wherein the transmitting unit assigns a plurality of first code channels to data transmission to a plurality of receiving stations.   The transmission station according to claim 8, wherein the transmission unit divides a frequency band for each transmission slot. A mobile communication system comprising a transmitting station and a receiving station,
The receiving station is
A receiving unit for receiving information indicating a frequency block distributed by the transmitting station ;
A reception channel state measurement unit for measuring a reception channel state of the frequency block based on information indicating the frequency block received by the reception unit ;
A control information generation unit that generates control information indicating a reception channel state of the frequency block to be notified to the transmission station based on the reception channel state measured by the reception channel state measurement unit;
A notification unit for notifying the transmission station of the control information generated by the control information generation unit ,
Before Symbol transmitting station,
A distribution unit that distributes a plurality of receiving stations to a frequency block obtained by dividing the frequency band ;
A notification unit for notifying the plurality of receiving stations of information indicating the frequency blocks distributed by the distribution unit;
It said plurality of based on the control information indicating the reception channel state notified the frequency blocks from the receiving station obtains an index related to the allocation of radio resources in the frequency block for each of the receiving stations, based on the indicator, the time domain mobile communication system, wherein the obtaining Bei a scheduler that performs scheduling. A transmitting station, a frequency block allocation method in a mobile communication system and a receiving station,
The receiving station is
A receiving step for receiving information indicating a frequency block distributed by the transmitting station ;
Measuring a reception channel state of the frequency block based on information indicating the frequency block received by the reception step ;
Generating control information indicating the reception channel state of the frequency block to be notified to the transmitting station based on the reception channel state measured by the step of measuring the reception channel state;
Notifying the transmitting station of the control information generated by the step of generating the control information,
The transmitting station is
Distributing a plurality of receiving stations to a frequency block obtained by dividing a frequency band ;
A notification step of notifying the plurality of receiving stations of information indicating the frequency block allocated by the distributing step;
Based on the control information indicating the reception channel state notified the frequency blocks from said plurality of receiving stations, seeking index regarding the allocation of radio resources in the frequency block in each of the receiving stations, based on the indicator, in the time domain frequency block allocation method characterized that you have a step of performing scheduling.

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