JP2008301422A - Communication system, terminal and base station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a communication system capable of having a frequency diversity effect independently of a sub-band width. <P>SOLUTION: In the communication system, a base station (10) is provided with an uplink scheduler (11) for determining a reference resource allocation pattern, an allocation pattern calculation part (17) for predicting a use resource pattern on the basis of the reference resource allocation pattern and a known pattern of frequency hopping and a traffic processing part (19) for receiving traffic in accordance with the reference resource allocation pattern or the use resource pattern. A terminal (20) is provided with an allocation pattern calculation part (23) for determining use resource information and a traffic transmission part (25) for transmitting the traffic by using an RU indicated by the reference resource allocation pattern or an RU indicated by the use resource information. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to resource allocation control when uplink transmission is performed using frequency hopping in a communication system to which an SC-FDMA scheme is applied.

  As an uplink transmission method using conventional SC-FDMA (Single Carrier-Frequency Division Multiple Access), for example, a plurality of terminals are grouped and assigned to a specific sub-band (subband), and (sub- A technique for performing frequency hopping (in band units) is disclosed (for example, Non-Patent Document 1 below). In addition, a method for compensating for a loss of average received energy on the receiving side by allocating the power of a portion that is not transmitted by frequency hopping pattern collision detection to the portion that performs transmission is disclosed (for example, the following patents) Reference 1).

Special table 2003-535556 gazette R1-070875 `` Frequency Hopping Pattern for UTRA Uplink '', NEC (2007-2)

  The conventional uplink transmission method (method of performing frequency hopping in units of subbands) has a problem that frequency diversity effect cannot be obtained because frequency hopping is not performed when the subband width is large. On the other hand, when the sub-bandwidth is small, there is a problem that the bandwidth allocated to one terminal is extremely small.

  The present invention has been made in view of the above, and in a communication system to which a method of performing frequency hopping in units of subbands is applied, it is possible to increase the degree of freedom of subband width selection without impairing the frequency diversity effect. An object of the present invention is to obtain a possible communication system, that is, a communication system capable of obtaining a frequency diversity effect even when the subband width is increased, and a terminal and a base station constituting the communication system.

  In order to solve the above-described problems and achieve the object, the present invention provides a base station that groups subordinate terminals and assigns them to specific subbands for each group. A communication system that performs frequency hopping in units of groups for each TTI that is a transmission cycle, and uses one or more RUs that are minimum allocation units of communication resources to perform single carrier transmission of traffic to the base station. The station uses a specific TTI to determine a reference resource allocation pattern indicating the number and arrangement of RUs allocated to each terminal, a reference resource allocation pattern determined by the scheduling means, and frequency hopping performed in a subband. Based on the known pattern, each terminal receives traffic at each TTI after the specific TTI. Transmission from each terminal according to a pattern predicting means for predicting a used resource pattern indicating the number and arrangement of RUs used in the transmission, and a reference resource allocation pattern determined by the scheduling means or a used resource pattern predicted by the pattern predicting means And a traffic receiving means for receiving the received traffic, wherein the terminal acquires a reference resource allocation pattern in the specific TTI from the base station, and executes the acquired reference resource allocation pattern and subband Based on a known pattern of hopping, resource information calculation means for determining used resource information indicating the number and arrangement of RUs used in each TTI after the specific TTI, and the RU or the resource indicated by the acquired reference resource allocation pattern Information calculation means decided Use RU indicated use resource information, characterized in that it comprises a traffic transmission means for transmitting the traffic.

  According to the present invention, since frequency hopping is performed even in the subband, for example, even when the subband width is large and frequency hopping in subband units is impossible, the frequency diversity effect can be obtained. , Has the effect.

  Embodiments of a communication system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration example of a terminal and a base station constituting a communication system according to the present invention.

  1 includes an uplink scheduler 11, a frequency hopping pattern generation unit 12, an allocation information transmission unit 13, a switch 14, a reference signal transmission unit 15, a multiplexing unit 16, an allocation pattern calculation unit 17, and a separation unit. 18 and a traffic processing unit 19. Each of these components is realized by hardware such as ASIC, FPGA, DSP, CPU, or software. In addition, the terminal 20 includes a separation unit 21, an allocation information reception unit 22, an allocation pattern calculation unit 23, a switch 24, a traffic transmission unit 25, a multiplexing unit 26, a reference signal reception unit 27, a channel quality measurement unit 28, and a CQI calculation unit. 29. Each of these components is realized by hardware such as ASIC, FPGA, DSP, CPU, or software. Hereinafter, operations of the base station 10 and the terminal 20 will be described.

  The uplink scheduler 11 of the base station 10 uses the well-known algorithm (for example, the Proportional Fairness algorithm) using the UE quality information of the terminal, the QoS information, and the channel quality information received from the subordinate terminals including the terminal 20. Generate a link assignment pattern. This pattern represents, for example, RU (Resource Unit) allocation (31 to 36) from UE1 to UE6 in TTI # 0 shown in FIG. 2, and “UE1 (offset: 0, number of RUs: 2), UE2 (offset: 2, RU number: 1), UE3 (offset: 3, RU number: 3), UE4 (offset: 6, RU number: 1), UE5 (offset: 7, RU number: 2), UE6 (offset: 9, RU number: 1) ”. Note that RU represents a frequency unit that can be divided as a resource (a minimum unit that can be allocated).

  The output of the uplink scheduler 11 is supplied to the frequency hopping pattern generation unit 12 and the allocation pattern calculation unit 17. The frequency hopping pattern generation unit 12 does nothing when the allocation of the example shown in FIG. 2 is a system band (outputs the uplink allocation pattern that is information received from the uplink scheduler 11 as it is). On the other hand, when the allocation shown in FIG. 2 indicates an allocation to a specific subband, a frequency hopping pattern to be executed for each subband is generated. That is, for example, as shown in FIG. 3, a hopping pattern for changing a subband assigned to a specific group (UE1 to UE4 in the example of FIG. 3) for each TTI (Transmission Time Interval) is generated. In this case, frequency hopping is also performed within the subband while performing frequency hopping in units of subbands. FIG. 3 shows only an example of a known “frequency hopping operation executed in subband units”, and shows an operation when the present invention is applied (frequency hopping is also performed in the subband. Is different). The generated information (frequency hopping pattern) is output together with the uplink allocation pattern received from the uplink scheduler 11.

  The output of the frequency hopping pattern generation unit 12 is supplied to the allocation information transmission unit 13. The allocation information transmission unit 13 performs necessary processing (for example, addition of UE information) on the output from the frequency hopping pattern generation unit, which is allocation information, and supplies it to the switch 14. The switch 14 is turned on when allocation information is necessary in the TTI, and is turned off when it is not necessary. That is, when the allocation by the uplink scheduler 11 is not changed (the control information output from the allocation information transmitting unit 13 is the same as the previous one), the control information is not transmitted to the terminal. By operating this switch 14 so as to transmit only necessary control information to the terminal, downlink signaling can be reduced. The output of the switch 14 is supplied to the multiplexing unit 16.

  The reference signal transmission unit 15 generates a predetermined pilot pattern. The pilot pattern is a predetermined pattern, and the signal transmission destination (terminal) performs synchronous detection based on this known information. The output of the reference signal transmission unit 15 is supplied to the multiplexing unit 16. The multiplexing unit 16 multiplexes the pilot signal input from the reference signal transmission unit 7 and the allocation information output from the allocation information transmission unit 13 and input via the switch 14. When the downlink resource block is composed of 12 subcarriers and 1 TTI is 14 symbols, the multiplexing unit 16 arranges, for example, pilot symbols at the 4th symbol so that the allocation information does not overlap with the pilot symbols (the 1st symbol, (2nd symbol, 3rd symbol, 5th symbol, etc.). Although not shown, the output of the multiplexing unit 16 is subjected to modulation (for example, QPSK modulation) and encoding (for example, turbo encoding), guardband insertion, IFFT (Inverse Fast Fourier Transform) baseband processing, and radio frequency. After being converted to, it is transmitted from the antenna to the terminal.

  The terminal 20 receives a signal from the base station 10 that has performed the above procedure by an antenna (not shown), performs synchronous detection, QPSK demodulation, and turbo decoding on the received signal, and then supplies the signal to the separation unit 21. . The separating unit 21 separates the pilot signal and the control signal, and supplies the pilot signal to the reference signal receiving unit 27 and the control signal to the allocation information receiving unit 22. The allocation information receiving unit 22 extracts allocation information addressed to itself (UE1) and supplies the extracted allocation information to the switch 24 and the allocation pattern calculation unit 23. For example, UE1 (offset 0, number of RUs: 2) in TTI # 0 is extracted and supplied to the switch 24 and the allocation pattern calculation unit 23.

  The allocation pattern calculation unit 23 corresponding to the resource information calculation unit calculates allocation information for each TTI based on the allocation information (uplink allocation pattern, frequency hopping pattern) received from the allocation information reception unit 22. For example, if the received allocation information is TTI # 0 information, the allocation information of TTI # 1, TTI # 2,. As a specific example, it is assumed that the frequency hopping pattern is a round robin type, and one resource unit is shifted per TTI, and the allocation information received from the allocation information receiving unit 22 is the TTI # 0 shown in FIG. Assuming that it is information, in TTI # 1, UE1 becomes (offset: 1, number of RUs: 2). Similarly, for TTI # 2 (offset: 2, number of RUs: 2), for TTI # 3 (offset: 3, number of RUs: 2), ..., for TTI # 8 (offset: 8, number of RUs: 2) , TTI # 9 is (offset: 9, number of RUs: 2). TTI # 10 is the same as TTI # 0, and the same uplink allocation pattern (pattern of TTI # 0 to TTI # 9) is repeated thereafter.

  Here, in the example illustrated in FIG. 2, the allocation to the UE 1 becomes a discontinuous carrier that is divided vertically by TTI # 9. Therefore, UE1 (terminal 20) secures single carrier transmission in the uplink by preventing transmission (DTX) in such a case (preventing occurrence of discontinuous carriers).

  The allocation information calculated by the allocation pattern calculation unit 23 is supplied to the switch 24. The switch 24 receives the allocation information from the allocation information receiving unit 22 and the allocation pattern calculating unit 23, and when there is an allocation from the base station to the own terminal (for example, at TTI # 0), from the allocation information receiving unit 22. On the other hand, if there is no assignment from the base station, the input from the assignment pattern calculation unit 23 is selected and supplied to the traffic transmission unit 25. Thus, this system has a configuration in which the base station 10 does not need to perform RU allocation for each TTI.

  The traffic transmission unit 25 selects a resource unit (RU) to be used based on the allocation information received from the switch 24. For example, in the case of TTI # 1, (offset: 1, number of RUs: 2) is selected, and in the case of TTI # 9, transmission is stopped (DTX). The output of the traffic transmission unit 25 is supplied to the multiplexing unit 26.

  The reference signal receiving unit 27 performs quadrature demodulation (for example, QPSK demodulation) and decoding on the pilot signal input from the separation unit 21 and supplies the result to the channel quality measurement unit 28. The channel quality measurement unit 28 measures channel quality (SIR: Signal to Interference Ratio) from the input pilot symbols. For this measurement, a well-known method is used in which the average value S of the pilot and the standard deviation are set to I. The channel quality information indicating the measurement result is supplied to the CQI calculation unit 29. The CQI calculation unit 29 calculates a CQI (Channel Quality Indicator) based on the channel quality information received from the channel quality measurement unit 28. This is an operation to convert (00000 to 11111) into a 5-bit value based on the SIR value (for example, -21 dB to 10 dB; total 32 dB). Specifically, -21 dB is made to correspond to 00000, and 10 dB to 11111. Make it correspond. The output of the CQI calculation unit 29 is supplied to the multiplexing unit 26.

  Multiplexer 26 multiplexes the output of traffic transmitter 25 and the output of CQI calculator 29. Specifically, the CQI is arranged at a predetermined position (for example, the first symbol of 1 TTI 6 symbols), and the traffic is arranged at the second symbol to the sixth symbol. The output of the multiplexing unit 26 is subjected to modulation (for example, QPSK modulation) encoding (for example, turbo encoding), converted to a radio frequency band, and transmitted from the antenna to the base station 10.

  The base station 10 receives a signal from the terminal 20 that has performed the above procedure with an antenna, and the received signal is converted from a radio frequency band to a baseband signal, and further demodulated and decoded, and then to the separation unit 18. Supplied. The separation unit 18 separates the channel quality information and the traffic information, and supplies the channel quality information to the uplink scheduler 11 and the traffic information to the traffic processing unit 19. As described above, the uplink scheduler 11 generates an uplink allocation pattern using channel quality information received from subordinate terminals including the terminal 20.

  The output of the uplink scheduler 11 is supplied to the frequency hopping pattern generation unit 12 and the allocation pattern calculation unit 17 described above. The allocation pattern calculation unit 17 (pattern prediction unit) that has received the output from the uplink scheduler 11 performs the same operation as the above-described allocation pattern calculation unit 23 of the terminal 1, and calculates allocation information for each TTI. In addition, when the base station 1 accommodates a plurality of terminals, allocation information for all terminals is calculated.

  The output of the allocation pattern calculation unit 17 is supplied to the traffic processing unit 19. Here, the allocation pattern calculation unit 17 identifies the RU (offset, the number of RUs) used by the transmission source terminal of the received signal (in this example, the terminal 20 or UE1), and supplies this identification result, The traffic processing unit 19 can extract the traffic information of the UE 1 based on the entire traffic information. The traffic processing unit 19 can recognize from the information received from the allocation pattern calculation unit 17 that UE1 is DTX in TTI # 9. When recognizing DTX, the traffic processing unit 19 treats that there is no traffic signal from the UE 1 (does not perform traffic processing).

  As described above, in the present embodiment, frequency hopping is performed within a subband while performing frequency hopping in units of subbands. This eliminates the necessity of reducing the sub-bandwidth, that is, the restriction of reducing the bandwidth allocated to the terminal. For example, even when the sub-band width is large and frequency hopping in units of sub-bands is impossible, frequency hopping is performed within the sub-band, so that a frequency diversity effect can be obtained. Also, for frequency hopping within the subband, each terminal allocates corresponding to each TTI based on initial allocation information notified from the base station (for example, allocation information for TTI # 0 shown in FIG. 2). Information is calculated, and it is determined whether single carrier transmission is possible for each TTI. Thereby, in TTI judged that single carrier transmission cannot be maintained, transmission can be stopped autonomously and single carrier transmission can be maintained. Further, since the terminal does not need to demodulate other allocation information, power consumption can be reduced. Furthermore, since the base station does not need to transmit allocation information unless the allocation pattern is changed, there is an effect that the amount of downlink signaling can be reduced.

  In the above description, uplink frequency hopping is described as a round robin type of one RU step, but the same effect can be obtained by using a round robin type of a plurality of RU steps or other hopping patterns.

  In FIG. 2, when the single carrier is not satisfied, the transmission of the carrier is stopped (referred to as DTX), but transmission may be performed using either one. FIG. 4 shows the operation of the allocation pattern calculation units 23 and 17 in such a case. For example, in TTI # 9, UE1 can transmit 1 RU instead of DTX. In this case, since the RU to be transmitted is not determined at random, but the side close to the lower band is deterministically selected as shown in the figure, the allocation pattern calculation unit 17 of the base station 10 correctly determines the traffic of each terminal. It becomes possible to extract. In this case, in addition to the effect in the case of performing the operation shown in FIG. 2, there is an effect that it is possible to reduce unnecessary idle resources in the uplink (the uplink can be used efficiently).

  Further, uplink resources are still generated even after the operation shown in FIG. 4 is performed. Therefore, as shown in FIG. 5, it is also possible to assign an empty pattern to another UE. In this case, the allocation pattern calculation unit 17 of the base station 10 performs TTI # 2 (offset: 0, number of RUs: 1), TTI # 5 (offset: 0, number of RUs: 1), TTI # 6 (offset: 0, Since it can be understood that the number of RUs: 2) and TTI # 9 (offset: 0, number of RUs: 1) are free, the uplink scheduler 11 is freed by providing this information to the uplink scheduler 11. What is necessary is just to allocate a resource to other UE (UE7 of illustration).

  Further, instead of the operation illustrated in FIG. 5, as illustrated in FIG. 6, it is also possible to additionally allocate resources to adjacent UEs of vacant resources. In this case, there are two possible methods for the terminal to know the additional assignment. The first is a method of receiving additional allocation information from the base station 20, and the second is a method in which the terminal receives allocation information of all terminals and grasps the resource allocation status for all terminals. That is, this is a method in which each terminal creates its own allocation information as shown in FIG. 6 based on the received allocation information and autonomously uses it for transmission when an additional allocation is made.

  In the methods shown in FIGS. 5 and 6, the uplink resources are effectively used as compared with the methods shown in FIGS. 2 and 4, so that the throughput is improved.

  In the method shown in FIG. 4, the side closer to the lower band is definitely selected, but transmission can also be performed using a larger resource unit group. FIG. 7 shows the operation of the allocation pattern calculation units 17 and 23 when realizing such an operation. In TTI # 6, the allocation of UE3 is (offset: 0, number of RUs: 2). Is the difference.

  FIG. 8 shows a method for assigning a new UE (UE7) to a free resource generated when the method shown in FIG. 7 is applied. Similarly, FIG. 9 shows a method of assigning free resources generated when the method shown in FIG. 7 is applied to neighboring UEs (additionally used by neighboring UEs). In either case, as compared with the methods shown in FIGS. 2 and 7, the uplink resources are effectively used, so that the throughput is further improved.

  As described above, compared with the transmission method of FIG. 2, the transmission method of FIGS. 4 and 7 increases the amount of traffic that can be transmitted. Furthermore, compared with the transmission method of FIGS. 4 and 7, the transmission method of FIGS. 6 and 9 increases the amount of traffic that can be transmitted. Therefore, if the increased ACK / NACK information and CQI for the downlink traffic signal are transmitted with priority over the increased traffic, the downlink throughput can be improved.

  Further, in the case where the uplink traffic signal is subjected to HARQ retransmission with respect to the increased traffic, the uplink throughput can be further improved by preferentially transmitting bits having a high degree of contribution to error decoding on the reception side.

Embodiment 2. FIG.
In the first embodiment described above, transmission of the carrier is stopped when the single carrier is not satisfied, but the combination is skipped when the single carrier is not satisfied next. Show. Note that the configurations of the base station and terminal in the present embodiment are the same as those in the first embodiment. However, since the operation is different, the difference will be mainly described with reference to FIG. FIG. 10 is a diagram illustrating an example of a resource allocation operation according to the second embodiment.

  In terminal 20 of the second embodiment, allocation information receiving unit 22 extracts allocation information transmitted to other terminals together with allocation information addressed to itself (UE1). For example, not only UE1 (offset: 0, number of RUs: 2) in TTI # 0 but also UE2 (offset: 2, number of RUs: 1), UE3 (offset: 3, number of RUs: 3), UE4 (offset: 6, RU number: 1), UE5 (offset: 7, RU number: 2), and UE6 (offset: 9, RU number: 1) are also extracted. The extracted allocation information of UE1 (allocation information addressed to itself) is supplied to the switch 24 as in the first embodiment, and the allocation information of all UEs is supplied to the allocation pattern calculation unit 23.

  The allocation pattern calculation unit 23 calculates allocation information (uplink allocation pattern) of TTI # 1, TTI # 2,... Based on the allocation information of TTI # 0 in FIG. As a specific example, it is assumed that the frequency hopping pattern is a round robin type and one resource unit is shifted per TTI, and the allocation information received from the allocation information receiving unit 22 is the TTI # 0 shown in FIG. Assuming that it is information, in TTI # 1, UE1 is (offset: 1, number of RUs: 2), UE2 is (offset 3, number of RUs: 1), UE3 is (offset: 4, number of RUs: 3), UE4 is (offset: 7, RU number: 1), UE5 is (offset 8, RU number: 2), and UE6 is (offset: 0, RU number: 1).

  In TTI # 2, UE1 has (offset 2, number of RUs: 2), UE2 has (offset: 4, number of RUs: 1), UE3 has (offset 5, number of RUs: 3), and UE4 has (offset: 8). , RU number: 1), UE5 is (offset 9, RU number: 2), UE6 is (offset: 1, RU number: 1), but UE5 is an allocation pattern that does not become a single carrier. As a result, in TTI # 2, UE1 (offset: 3, number of RUs: 2), UE2 (offset 5, number of RUs: 1), UE3 (offset: 6, number of RUs: 3), UE4 is (offset 9, number of RUs: 1), UE5 is (offset: 0, number of RUs: 2), and UE6 is (offset 2, number of RUs: 1).

  Similarly, in TTI # 3, UE1 is (offset 4, number of RUs: 2), UE2 is (offset: 6, number of RUs: 1), UE3 is (offset 7, number of RUs: 3), and UE4 is (offset) : 0, number of RUs: 1), UE5 is (offset 1, number of RUs: 2), UE6 is (offset: 3, number of RUs: 1), and in TTI # 4, UE1 is (offset: 7, number of RUs: 2), UE2 (offset 9, number of RUs: 1), UE3 (offset: 0, number of RUs: 3), UE4 (offset 3, number of RUs: 1), UE5 (offset: 4, number of RUs: 2) UE6 is (offset 6, number of RUs: 1). In TTI # 5, UE1 (offset: 8, number of RUs: 2), UE2 (offset 0, number of RUs: 1), UE3 (offset: 1, number of RUs: 3), UE4 (offset 4, RU) Number: 1), UE5 is (offset: 5, RU number: 2), and UE6 is (offset 7, RU number: 1).

  Hereinafter, TTI # 6 has the same allocation pattern as TTI # 0. Thus, the allocation pattern calculation unit 23 can autonomously determine the RU transmitted by itself (UE1) after TTI # 1. The operation of the allocation pattern calculation unit 17 of the base station 10 is the same.

  Thus, in the present embodiment, a pattern that does not become a single carrier is skipped. As a result, no extra free resources are generated, so that uplink throughput can be improved. In addition, since frequency hopping is performed in the subband as in the first embodiment, it is not necessary to reduce the subband width in order to obtain the frequency diversity effect, and the degree of freedom of the allocated bandwidth of the terminal can be increased. .

Embodiment 3 FIG.
In the above embodiment, the description has been made as if the change of the hopping cycle of the terminal is not changed, but the allocation can be changed even in the middle of the hopping cycle as described below. FIG. 11 shows an allocation method in such a case, where the horizontal axis indicates time and the vertical axis indicates frequency channels. All terminals in the same cell are assumed to have the same hopping cycle timing. This may be set in advance as a default value in the terminal, or may be notified from a higher layer via a base station or the like.

  FIG. 11 shows two types of hopping patterns {1-0, 1-1, 1-2, 1-3, 1-4} and {2-0, 2-1, 2-2, 2-3, 2- 4}, the terminal that has received the uplink resource allocation in the middle of the cycle calculates how far the timing at which uplink transmission is first performed is from the top of the hopping cycle (N ms).

  Transmission is started using an RU group corresponding to the Kth (starting with 0) of a predetermined hopping pattern. Thereafter, the RU group is changed at each hopping timing (one slot or one subframe) according to the determined hopping pattern. The calculation of K uses SFN and subframe number.

  The example of FIG. 11 represents a case where K = 2 and a terminal that has been assigned a hatched RU group starts transmission from the second hopping timing of the hopping cycle.

  As described above, according to the method of the present embodiment, uplink transmission can be started even in the middle of the hopping cycle timing, and even if uplink transmission is started in the middle, hopping is already performed at another timing with uplink allocation. There is no collision with the terminal.

Embodiment 4 FIG.
In this embodiment, in order to efficiently implement single carrier transmission of a terminal that does not perform hopping, an RU allocated to a terminal that performs hopping is arranged at the end of the system frequency band, and there are a plurality of subbands that perform hopping. If so, make them adjacent. FIG. 12-1 represents this concept. There are two groups as hopping subbands, which are adjacent to each other and arranged at the end of the system frequency band at times TTI # 0 and TTI # 1. FIG. 12-2 shows an arrangement of hopping subbands not based on the above-described concept. The subband indicated by the white box is an RU to which a terminal that does not perform hopping is assigned. In the case of FIG. 12B, the area of the white box is divided into two or three. In uplink communication, since all terminals are single carrier transmission, a plurality of regions divided on the frequency axis cannot be assigned to one terminal. That is, in the case of FIG. 12-2, the maximum number of subbands that can be allocated to one terminal is 3 in TTI # 1. This leads to a reduction in the maximum throughput of the terminal. On the other hand, in the case of FIG. 12-1, the subbands to be hopped are always arranged at the end of the system frequency band and a plurality of hopping subbands are adjacent to each other. is made of. This can be expected to improve the maximum throughput of the terminal. In addition to the maximum throughput of one terminal, if a large continuous area exists, the scheduler can be given flexibility in assigning resources to a plurality of terminals.

  As described above, the communication system according to the present invention is useful for wireless communication, and is particularly suitable for effective use of resources in the uplink of a communication system to which the SC-FDMA scheme is applied.

2 is a diagram illustrating a configuration example of a base station and a terminal according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an uplink resource allocation pattern according to Embodiment 1. FIG. It is a figure which shows an example of a frequency hopping operation | movement. 6 is a diagram illustrating an example of an uplink resource allocation operation according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an uplink resource allocation operation according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an uplink resource allocation operation according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an uplink resource allocation operation according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an uplink resource allocation operation according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an uplink resource allocation operation according to Embodiment 1. FIG. FIG. 10 is a diagram illustrating an example of an uplink resource allocation operation according to the second embodiment. FIG. 10 is a diagram illustrating an example of a frequency hopping operation according to a third embodiment. FIG. 10 is a diagram for explaining an uplink resource allocation operation according to the fourth embodiment. FIG. 10 is a diagram for explaining an uplink resource allocation operation according to the fourth embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Base station 11 Uplink scheduler 12 Frequency hopping pattern generation part 13 Allocation information transmission part 14, 24 Switch 15 Reference signal transmission part 16, 26 Multiplexing part 17, 23 Assignment pattern calculation part 18, 21 Separation part 19 Traffic processing part 20 Terminal 22 Assignment information receiving unit 25 Traffic transmitting unit 27 Reference signal receiving unit 28 Channel quality measuring unit 29 CQI calculating unit

Claims (16)

The base station groups the subordinate terminals and assigns them to specific subbands for each group, and each terminal performs frequency hopping in units of groups for each TTI that is a signal transmission period within the system band, and A communication system that uses one or a plurality of RUs, which are minimum allocation units, to transmit single-carrier traffic to the base station,
The base station
Scheduling means for determining a reference resource allocation pattern indicating the number and arrangement of RUs allocated to each terminal at a specific TTI;
Based on a reference resource allocation pattern determined by the scheduling means and a known pattern of frequency hopping executed in a subband, the number and arrangement of RUs used by each terminal for traffic transmission in each TTI after the specific TTI A pattern prediction means for predicting the resource pattern used;
Traffic receiving means for receiving traffic transmitted from each terminal according to a reference resource allocation pattern determined by the scheduling means or a use resource pattern predicted by the pattern prediction means;
With
The terminal
A reference resource allocation pattern for the specific TTI is acquired from the base station, and is used for each TTI after the specific TTI based on the acquired reference resource allocation pattern and a known pattern of frequency hopping executed in a subband. Resource information calculating means for determining used resource information indicating the number and arrangement of RUs;
Traffic transmitting means for transmitting traffic using the RU indicated by the acquired reference resource allocation pattern or the RU indicated by the used resource information determined by the resource information calculating means;
A communication system comprising: When the determined use resource information indicates a resource pattern of multicarrier transmission, the traffic transmission means stops transmission processing with a TTI corresponding to the use resource information,
The traffic reception means determines whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the used resource pattern, and forms a resource pattern for multicarrier transmission The communication system according to claim 1, wherein reception processing from the specific terminal is stopped. When the determined use resource information indicates a resource pattern of multicarrier transmission, the traffic transmission unit selects any one resource based on a predetermined condition in a TTI corresponding to the use resource information, Perform single carrier transmission with the selected resource,
The receiving means determines whether or not a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the resource pattern used, and forms a resource pattern for multicarrier transmission. 2. The communication system according to claim 1, wherein any one resource is selected based on a predetermined condition, and traffic from the specific terminal is received by the selected resource.   The scheduling means determines whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the resource pattern used, and forms a resource pattern for multicarrier transmission. 4. The communication system according to claim 3, wherein a resource that the specific terminal does not use for traffic transmission is specified based on a predetermined condition, and the specified resource is allocated to a terminal other than the specific terminal. The resource information calculation means determines used resource information for each terminal based on the reference resource allocation pattern and the known pattern of the frequency hopping,
Based on the determined use resource information, the traffic transmission means checks whether a band adjacent to its own use band is used by another terminal, and if it is not used by another terminal, 5. The communication system according to claim 1, wherein the adjacent band is also used for single carrier transmission of traffic. The resource information calculation means includes
Based on the reference resource allocation pattern and the known pattern of the frequency hopping, a candidate for used resource information for each terminal is determined for each TTI,
Further, when the use resource information candidate confirms whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission, and forms a resource pattern for multicarrier transmission, the use resource information candidate and this When all the used resource information candidates determined for each terminal and each TTI corresponding to the candidates are discarded, and when a resource pattern for multicarrier transmission is not formed, the used resource information candidates are used resource information,
The pattern prediction means confirms whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the predicted use resource pattern, and forms a resource pattern for multicarrier transmission. The communication system according to claim 1, wherein the predicted use resource pattern is discarded. For base stations that group subordinate terminals and assign to specific subbands for each group, perform frequency hopping in units of groups for each TTI that is the signal transmission period within the system band, and in units of minimum allocation of communication resources A terminal that uses one or more RUs to transmit traffic on a single carrier,
A reference resource allocation pattern indicating the number and arrangement of RUs used in traffic transmission with a specific TTI is acquired from the base station, and based on the acquired reference resource allocation pattern and a known pattern of frequency hopping executed in a subband. Resource information calculating means for determining used resource information indicating the number and arrangement of RUs used in each TTI after the specific TTI;
Traffic transmitting means for transmitting traffic using the RU indicated by the acquired reference resource allocation pattern or the RU indicated by the used resource information determined by the resource information calculating means;
A terminal comprising:   The said traffic transmission means stops the transmission process by TTI corresponding to the said used resource information, when the determined used resource information has shown the resource pattern of multicarrier transmission. The listed terminal.   When the determined use resource information indicates a resource pattern of multicarrier transmission, the traffic transmission unit selects any one resource based on a predetermined condition in a TTI corresponding to the use resource information, The terminal according to claim 7, wherein single-carrier transmission is performed using the selected resource. The resource information calculation means determines used resource information for each terminal based on the reference resource allocation pattern and the known pattern of the frequency hopping,
Based on the determined use resource information, the traffic transmission means checks whether a band adjacent to its own use band is used by another terminal, and if it is not used by another terminal, The terminal according to claim 7, 8 or 9, wherein the adjacent band is also used for single carrier transmission of traffic. The resource information calculation means includes
Based on the reference resource allocation pattern and the known pattern of the frequency hopping, a candidate for used resource information for each terminal is determined for each TTI,
Further, when the use resource information candidate confirms whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission, and forms a resource pattern for multicarrier transmission, the use resource information candidate and this In the case where all of the use resource information candidates determined for each terminal and each TTI corresponding to the candidates are discarded, and when no resource pattern for multicarrier transmission is formed, the use resource information candidates are used as the use resource information. The terminal according to claim 7. Grouped and assigned to a specific subband for each group, performs frequency hopping for each TTI that is a signal transmission period within the system band, and one or a plurality of RUs that are the minimum allocation unit of communication resources A base station that accommodates terminals that use single carrier transmission of traffic,
Scheduling means for determining a reference resource allocation pattern indicating the number and arrangement of RUs allocated to each terminal at a specific TTI;
Based on a reference resource allocation pattern determined by the scheduling means and a known pattern of frequency hopping executed in a subband, the number and arrangement of RUs used by each terminal for traffic transmission in each TTI after the specific TTI A pattern prediction means for predicting the resource pattern used;
Traffic receiving means for receiving traffic transmitted from each terminal according to a reference resource allocation pattern determined by the scheduling means or a use resource pattern predicted by the pattern prediction means;
A base station comprising:   The traffic reception means determines whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the used resource pattern, and forms a resource pattern for multicarrier transmission The base station according to claim 12, wherein reception processing from the specific terminal is stopped.   The receiving means determines whether or not a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the resource pattern used, and forms a resource pattern for multicarrier transmission. 13. The base station according to claim 12, wherein one of the resources is selected based on a predetermined condition, and traffic from the specific terminal is received using the selected resource.   The scheduling means determines whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the resource pattern used, and forms a resource pattern for multicarrier transmission. 15. The base station according to claim 14, wherein a resource that the specific terminal does not use for traffic transmission is specified based on a predetermined condition, and the specified resource is allocated to a terminal other than the specific terminal.   The pattern prediction means confirms whether a resource pattern corresponding to a specific terminal forms a resource pattern for multicarrier transmission based on the predicted use resource pattern, and forms a resource pattern for multicarrier transmission. In this case, the base station according to claim 12, wherein the predicted use resource pattern is discarded.

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