JP2003152671A - Orthogonal frequency division multiplex system and transmitter-receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the processing amount for transmission power control by reducing a control information amount. SOLUTION: By measuring the receiving power of each of subcarriers in an OFDM signal in a receiving power measuring part 22, the continuous subcarriers defined as receiving power, which does not exceed a threshold ΔE preset in a control part 26, are collected into block. The control part 26 generates control information composed of transmitting power control information, with which the receiving power in each of blocks becomes almost equal, and the top subcarrier numbers of respective blocks and this information is reported from a mobile station 2 to a base station 1. In the base station 1, the control information is saved on a control information managing table 16a in a control part 16 and on the basis of this control information, the transmitting power of subcarriers in the OFDM signal to be transmitted to the mobile station 2 is controlled for each block.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an orthogonal frequency division multiplexing system using a large number of orthogonal subcarriers.

[0002]

2. Description of the Related Art High quality digital audio broadcasting (DSB: Digital Sound Broadc) for mobiles in Europe and Canada.
asting) is under development. In this audio broadcasting system, an orthogonal frequency division multiplex communication system (OFDM: Orthogonal Fres
quency Division Multiplexing) has been adopted. In this OFDM communication system, an information data sequence is transmitted using a large number of subcarriers that are orthogonal to each other. In this case, since one symbol length can be increased, ghost interference can be reduced. Furthermore, by providing a guard interval, it becomes strong against frequency selective fading. Further, frequency interleaving is possible in addition to time interleaving, and the effect of error correction can be used effectively. Furthermore, the spectrum of each subcarrier can be densely arranged, and the frequency utilization efficiency can be improved. Furthermore, since information can be arbitrarily assigned to each subcarrier, it is possible to enable flexible information transmission such as not using a subcarrier in which interference is expected.

[0003]

By the way, in the case of realizing a high-speed transmission system, there arises a problem that the required received power increases as the bandwidth increases. Therefore, the transmission power can be reduced by applying the transmission power control used in the conventional CDMA communication system to the OFDM communication system. By performing transmission power control, it is possible to set the transmission power based on many terminals located at the cell edge, and it is possible to reduce the excessive transmission power that was conventionally consumed by many terminals around the base station. become able to. Furthermore, in an OFDM communication system, when an OFDM signal undergoes fading in a propagation path, the average received signal power fluctuates, but by performing transmission power control, fluctuations in the average received signal power due to fading can be compensated. . As a result, transmission quality is improved, and good transmission quality can be achieved with low transmission power.

However, when the transmission power control is applied to the OFDM communication system, the fluctuation of the average reception power level is compensated, but the fluctuation of the reception power level for each subcarrier caused by the influence of frequency selective fading is also compensated. I can't. Here, the effect of receiving frequency selective fading in the OFDM communication system will be described. FIG. 13 is an example of a transmitted OFDM signal in the OFDM communication system. This OFDM signal is composed of many subcarriers, and each subcarrier is transmitted with the same transmission power. When such an OFDM signal propagates in a multipath environment, it is affected by frequency selective fading, and the received power between subcarriers varies. In this case, the variation characteristic changes variously depending on the environment of the propagation path. For example, in an OFDM signal that has undergone frequency selective fading in the propagation path, the received power between subcarriers varies as shown in FIG. As a result, the predetermined transmission quality cannot be satisfied in the subcarrier having the low received power level.

Therefore, in order to prevent the received power from varying for each subcarrier as described above, a method of controlling the transmission power for each subcarrier has been proposed.
SSE2000-71, RCS2000-60 (2000-07) Tomoaki Yoshigiri, 2 persons, "Characteristics when applying multi-level transmission power control in OFDM subcarrier adaptive modulation system"). This technique aims at applying transmission power control to an OFDM communication system, and is composed of a transmission power control for the entire received signal level and a transmission power control for a level according to the modulation level of each subcarrier. The transmission power is controlled. In this multi-level transmission power control, the transmission power is controlled for each sub-carrier so that the sub-carriers to which each modulation multi-level number is allocated satisfy the required BER, and extremely high reception power that may consume higher transmission power. By not allocating transmission power to subcarriers with low power level, power efficiency is improved.

However, in order to effectively perform the transmission power control for each subcarrier according to the state of the propagation path, information about the transmission power control for each subcarrier based on the reception power measured at the reception side is transmitted. Need to be notified. Therefore, in order to control the transmission power for each subcarrier, a large amount of control information is required on the transmission side or the reception side, and the processing amount and storage amount of the transmission power control become heavy. Furthermore, since the processing amount and storage amount of the transmission power control depend on the number of subcarriers, the processing amount and storage amount further increase as the number of subcarriers increases,
The problem arises that its feasibility becomes difficult.

Therefore, an object of the present invention is to provide an orthogonal frequency division multiplexing system and a transmission / reception apparatus which can reduce the amount of control information and the processing amount and storage amount of transmission power control.

[0008]

In order to achieve the above object, an orthogonal frequency division multiplexing system of the present invention receives an orthogonal frequency division multiplexed signal transmitted from a transmitting side with a fixed transmission power at a receiving side. According to the received power values of a plurality of subcarriers forming the received orthogonal frequency division multiplex signal, the subcarriers are grouped into a block composed of some of the subcarriers, and the number of the subcarrier at a specific position in the block. And the difference information between the reception power value and the specified reception power in each of the blocks is notified to the transmission side, and the transmission side that has received the subcarrier number and the difference information receives an orthogonal frequency division multiplexed signal. Are divided into blocks based on the numbers of the subcarriers, and are divided based on the difference information. So as to control the transmission power of the subcarrier block.

Further, in the above-mentioned orthogonal frequency division multiplexing system of the present invention, subcarriers whose received power difference between subcarriers falls within a predetermined threshold may be grouped into the blocks. . Furthermore, in the above-mentioned orthogonal frequency division multiplexing system of the present invention, when the plurality of subcarriers are divided into the blocks, a block having the minimum number of subcarriers included in the divided blocks is obtained, and The block length may be the block length of the obtained block.

Furthermore, in the above-mentioned orthogonal frequency division multiplexing system of the present invention, the number of subcarriers when dividing into blocks is referred to by referring to the table of the cumulative value of the probability distribution in which the number of subcarriers exists with respect to the number of subcarriers. You may ask. Furthermore, in the orthogonal frequency division multiplexing system of the present invention, for a block in which the reception power on the reception side does not reach a predetermined minimum reception power value, the transmission power of the block is calculated on the transmission side based on the difference information. It may be distributed to other blocks.

A transmitter / receiver of the present invention that can achieve the above object is a transmitter / receiver capable of transmitting and receiving an orthogonal frequency division multiplex signal, and is capable of transmitting an orthogonal frequency division multiplex signal transmitted at a fixed transmission power. Depending on the received power values of the plurality of subcarriers that are configured, dividing means for grouping the blocks into a number of subcarriers, and the number of the subcarrier at a specific position in each block divided by the dividing means And control means for obtaining difference information between the received power value and the specified received power in each of the divided blocks, and the control information including the subcarrier number and the difference information is stored in the control means of the control means. Under control, it is transmitted every predetermined period.

Further, in the transmitting / receiving device of the present invention,
You may make it divide | segment into the said block by putting together the subcarriers with which the difference of the received power between subcarriers is set within the predetermined threshold value. Furthermore, in the transmitting / receiving apparatus of the present invention, when the plurality of subcarriers are divided into a plurality of blocks, a block having the minimum number of subcarriers included in the divided blocks is obtained, and the block lengths of all blocks May be set to the block length of the obtained block.

Furthermore, in the transmitting / receiving apparatus of the present invention, the number of subcarriers when dividing into blocks is obtained by referring to a table of cumulative values of probability distributions in which the number of subcarriers exists with respect to the number of subcarriers. May be. Furthermore, in the transmitting / receiving device of the present invention,
For a block whose received power does not reach a predetermined minimum received power value, the control means may create control information for distributing the transmission power of the block to other blocks.

According to the present invention as described above, the subcarriers are grouped into blocks according to the received power, and the transmission power control is performed for each block. As described above, since the transmission power control is performed for each block in which some subcarriers are collected, it is possible to reduce the control information amount and the transmission power control processing amount and storage amount. become able to. Such transmission power control processing is performed every time a pilot signal is transmitted from the transmission side with a fixed transmission power. Further, as described above, the adjacent subcarriers have a high frequency correlation, and the fluctuations in the received power due to the effect of frequency selective fading on the subcarriers within a certain correlation bandwidth can be considered to be almost equal. Because you can. Therefore, the block configuration becomes adaptive to a specific change in the propagation path, and efficient transmission power control can be performed. Therefore, the orthogonal frequency division multiplexing system of the present invention can enable high-speed transmission and high-quality transmission.

[0015]

FIG. 1 shows an example of the configuration of an orthogonal frequency division multiplexing system according to an embodiment of the present invention. However, although the base station 1 and one mobile station 2 are shown in FIG. 1, there are many mobile stations, and only the mobile station 2 among them is shown. The mobile station 2 corresponds to the transmitting / receiving device according to the embodiment of the present invention. In FIG. 1, the base station 1 includes an OFDM modulator 10, an OFDM demodulator 17, and a control unit 16 that controls transmission power. This O
The FDM demodulator 17 uses the OFD in the mobile station 2 described later.
The configuration is such that the reception power measuring unit 22 of the M demodulator 20 is omitted. The transmission data is applied to the encoder 11 in the OFDM modulator 10, is subjected to encoding such as error correction encoding and compression encoding, and is symbol-modulated in the symbol modulator 12. In the symbol modulator 12, modulation such as BPSK, QPSK, 16QAM or 32QAM is performed according to the transmission speed and the required transmission quality. The modulation symbol output from the symbol modulator 12 is converted into a parallel number of modulation symbols corresponding to the number of subcarriers in the serial-parallel conversion unit (S / P conversion unit) 13.
As a result, the symbol rate of the modulation symbol output from the S / P converter 13 is reduced to 1 / the number of subcarriers.

The parallel modulation symbol, which is the number of subcarriers output from the S / P converter 13, is the transmission power controller 1
4 by the transmission power control signal from the control unit 16,
The transmission power is controlled for each block described later.
This block consists of several subcarriers. The parallel modulation symbol, which has the number of subcarriers for which transmission power control is performed by the transmission power control unit 14, is inverse Fourier transformed by the inverse fast Fourier transform unit (IFFT) 15 to be an OFDM signal. IFFT15 is
An inverse discrete Fourier transform unit (IDFT) may be used. This OFDM signal is transmitted from the base station 1 on a carrier having a predetermined frequency.

Mobile station 2 capable of receiving this OFDM signal
Includes an OFDM demodulator 20, an OFDM modulator 27, and a control unit 26. This OFDM modulator 27
Has a configuration in which the transmission power control unit 14 of the OFDM modulator 10 in the base station 1 is omitted. The OFDM signal received by the mobile station 2 is a fast Fourier transform unit (FF
In (T) 21, the Fourier transform is applied and decomposed for each subcarrier. The FFT 21 may be a discrete Fourier transform unit (DFT). The reception power of each subcarrier output in parallel from the FFT unit 21 is measured by the reception power measuring unit 22, and the reception power value of each subcarrier is supplied to the control unit 26. The subcarriers output in parallel from the FFT unit 21 are supplied to the parallel-serial conversion unit (P / S conversion unit) 23 via the reception power measurement unit 22, and the modulation symbols of the parallel subcarriers are serialized. Are converted to modulation symbols of. This P / S converter 23
The modulation symbol of the subcarrier output from is demodulated by the symbol demodulation unit 25 to be demodulated data.
In the symbol demodulation unit 25, BPSK, QPSK, 16QAM or 32QAM applied on the transmitting side is used.
Demodulation is performed according to the modulation such as. Symbol demodulator 25
The demodulated data output from is subjected to error correction, decompression processing, etc. in the decoder 24 and is decoded into received data and output.

The control unit 26 divides the block into a number of subcarriers according to the received power value of each subcarrier supplied from the received power measurement unit 22. Then, control information including the subcarrier number of the first subcarrier of the divided block and the transmission power control information for controlling the transmission power so that the reception power of the block becomes the specified reception power is sent to the OFDM modulator 27. Supply. In this case, the last subcarrier number may be used instead of the first subcarrier number. In the OFDM modulator 27, the control information is periodically transmitted from the mobile station 2 to the base station 1. In order to measure the reception power of the subcarriers at the mobile station 2, the base station 1 periodically transmits an OFDM-modulated pilot signal for which transmission power control is not performed. Then, the mobile station 2 obtains control information by measuring the received power of this pilot signal. In this way, the channel for controlling the transmission power in the base station 1 is the communication channel set for each mobile station. Since this transmission power control is performed according to the control information transmitted from the mobile station, different transmission power control is performed for each mobile station.

Next, specific processing of transmission power control in the orthogonal frequency division multiplexing system shown in FIG. 1 will be described in detail with reference to FIGS. FIG. 2 shows an OFDM signal which is a pilot signal in the control channel in which the transmission power transmitted from the base station 1 has a fixed value. The subcarriers of this OFDM signal are assumed to be composed of, for example, subcarriers SC1 to SC23. SC1 to SC23 are subcarrier numbers. Subcarrier SC1
When an OFDM signal composed of subcarriers of subcarrier SC23 is affected by frequency selective fading in a propagation path of a multipath environment, for example, FIG.
As shown in, the subcarrier envelope fluctuates. That is, the level of each subcarrier in the OFDM signal received by the mobile station 2 will change.

Then, the reception power values of the subcarriers SC1 to SC23 measured by the reception power measuring unit 22 in the mobile station 2 are as shown by the length of the spectrum indicated by the arrow in FIG. Become. This received power value is represented as {E1, E2, ..., En}. However, E1 is the reception power value of subcarrier SC1, E2 is the reception power value of subcarrier SC2, and En is the reception power value of the last subcarrier (subcarrier SC23 in the case shown, that is, n = 23). . In this case, adjacent subcarriers have a high frequency correlation, and it can be considered that variations in received power due to the effect of frequency selective fading on subcarriers within a certain correlation bandwidth are almost the same. Then, using this, next, the subcarrier S
The control unit 26 divides C1 to subcarrier SC23 into blocks each including several subcarriers. When the control unit 26 divides the block into blocks, one sub-carrier is defined as consecutive sub-carriers that fall within ± ΔE of the reception power value of the leading sub-carrier. That is, | Eh−Ei | <ΔE is calculated, and consecutive subcarriers corresponding to the received power value Ei satisfying the given expression are set as the subcarriers of the block. However, Eh is the received power value corresponding to the subcarrier at the beginning of the block. Further, the subcarriers having the received power less than the threshold value Emin of the minimum received power are put together into one block.

In this case, if the threshold value ΔE is decreased, the number of blocks is increased, and if the threshold value ΔE is increased, the number of blocks is decreased. As described above, the number of blocks can be divided into an arbitrary number of blocks, but the threshold value ΔE is such that the number of blocks can be obtained so that the fluctuations in the received power due to the effect of frequency selective fading can be considered to be almost equal. Make sure to determine the value in advance. In this case, BER
The range in which (Bit Error Rate) is approximately equal can be considered to be approximately the same in fluctuations in received power due to the effect of frequency selective fading. When the subcarriers of the OFDM signal affected by frequency selective fading shown in FIG. 3 are divided into blocks using the threshold value ΔE determined in this way, it becomes as shown in FIG.
That is, the first block B1 includes the subcarriers SC1 to S1.
C5, the second block B2 is composed of subcarriers SC6 to SC8, the third block B3 is composed of subcarriers SC9 to SC11, the fourth block B4 is composed of subcarriers SC12 to SC14, and the fifth block. B5 is a subcarrier SC15, SC
16, the sixth block B6 is composed of subcarriers SC17 and SC18, the seventh lock B7 is composed of subcarriers SC19 and SC20, and the eighth block B6 is composed of subcarriers SC17 and SC20.
The block B8 is composed of the subcarriers SC21 to SC23. In this way, the block length is divided according to the intensity of fluctuation.

By thus forming the blocks in the control unit 26, each block can be configured by subcarriers that fall within the threshold value ΔE. Instead of this blocking, the control unit 26 may be blocked as shown in FIG. In the block formation shown in FIG. 5, the number of subcarriers included in one block is set as a fixed value and divided into blocks. In this case, the number of subcarriers included in one block is the number of subcarriers in the block having the smallest number of subcarriers when the blocks are formed on the condition that they fall within the threshold value ΔE as shown in FIG. In the case shown in FIG. 4, since the fifth block B5 to the seventh block B7 are composed of two subcarriers, each block B5 to B11 is divided into blocks so as to be composed of two subcarriers as shown in FIG. .

Next, as shown in FIG. 4, after dividing into blocks, the control unit 26 creates transmission power control information for controlling the transmission power so that each block can receive with substantially the same reception power. This transmission power control information defines the prescribed value Eth of the reception power as shown in FIG. 6, and obtains the difference between this prescribed value Eth and the minimum value of the reception power value of the subcarrier in each block as the transmission power control information. . For example, in the example shown in FIG. 6, the transmission power control information of the first block B1 is the difference EB1 between the minimum reception power of the subcarrier SC5 in the first block B1 and the specified value Eth. When the base station 1 controls the transmission power by the transmission power control information EB1, the transmission power of the first block B1 is reduced by an amount corresponding to the transmission power control information EB1. This is because the reception power of the subcarrier SC5 exceeds the specified value Eth. Further, the transmission power control information of the second block B2 is the difference EB2 between the reception power of the smallest subcarrier SC8 in the second block B2 and the specified value Eth. When the base station 1 controls the transmission power by the transmission power control information EB2, the transmission power of the second block B2 is increased by an amount corresponding to the transmission power control information EB2. This is because the reception power of the subcarrier SC8 is less than the specified value Eth.

Similarly, the transmission power control information of the third block B3 becomes EB3, and this transmission power control information EB3
When the transmission power is controlled by the base station 1, the transmission power of the third block B3 is increased by the amount corresponding to the transmission power control information EB3. Furthermore, the fourth block B4
Is EB4, and when the transmission power control information EB4 controls the transmission power in the base station 1, the transmission power of the fourth block B4 is increased by the amount corresponding to the transmission power control information EB4. . Further, since the fifth block B5 is the block of the subcarriers SC15 and SC16 that does not reach the threshold value Emin of the minimum reception power, the subcarriers SC15 and S15 of the fifth block B5 are included.
It is the transmission power control information EB5 that does not transmit C16.
This is because the threshold value Emin is a level near the level of the background noise on the receiving side in the mobile station 2,
The reception power of the subcarriers SC15 and SC16 of the fifth block B5 cannot be measured accurately, and the fifth block B5 consumes high transmission power when the transmission power is controlled, so that the transmission of other blocks is relatively performed. This is because the power will be reduced.

Furthermore, the transmission power control information of the sixth block B6 becomes EB6, and this transmission power control information EB6
Thus, when the transmission power is controlled in the base station 1, the transmission power of the sixth block B6 is increased by the amount corresponding to the transmission power control information EB6. Furthermore, the transmission power control information of the seventh block B7 becomes EB7, and when the transmission power is controlled in the base station 1 by this transmission power control information EB7, the transmission power of the seventh block B7 becomes the transmission power control information EB7. It is increased by a corresponding amount. Furthermore, the transmission power control information of the eighth block B8 becomes EB8, and when the transmission power control is performed in the base station 1 by this transmission power control information EB8, the transmission power of the eighth block B8 becomes the transmission power control information EB8. It is reduced by a corresponding amount.

Control information consisting of the transmission power control information in each block and the number information of the leading subcarrier of each divided block is sent from the control unit 26 to OF.
It is supplied to the DM modulator 27. In the OFDM modulator 27, control information is periodically inserted into communication data as shown in FIG. 8 and transmitted from the mobile station 2 to the base station 1. The control information transmission cycle is a cycle in which the characteristics of frequency selective fading on the propagation path do not change significantly.

The base station 1 receives the control information transmitted from the mobile station 2, the OFDM demodulator 17 demodulates the control information, and the demodulated control information is supplied to the control unit 16. The communication data is demodulated by the OFDM demodulator 17 and output as received data. The demodulated control information is supplied to the control unit 16 and stored in the built-in control information management table 16a. Since the control information is sent periodically, the control information on the control information management table 16a is updated every time it is received. Therefore, even if the influence of frequency selective fading in the propagation path changes,
The control information following the change is the control information management table 1
It is stored in 6a. Further, the control information management table 16a stores the control information of the mobile stations located in the base station 1.

When controlling the transmission power of the communication channel, the control unit 16 stores the control information of the mobile station corresponding to the set communication channel in the control information management table 16a.
Read from. Next, the subcarriers are divided into blocks based on the subcarrier number at the head of the block in the control information. Further, the transmission power control of the block is performed based on the transmission power control information of each divided block in the control information. In this case, the sum of the transmission power of each block is always equal. That is, when the transmission power control information is changed, the transmission power in each block is changed according to the control information, but the sum of the transmission power of each block is the sum of the transmission power before the change. Is equal to

Here, FIG. 7 shows an example of the transmission power of each block of the OFDM signal whose transmission power is controlled by the transmission power control unit 14 in the base station 1 based on the transmission power control information shown in FIG. As shown in FIG. 6, the first block B1
And in the eighth block B8, the received power is the specified value E
Since it exceeds th, the transmission power is reduced. Further, since the fifth block B5 does not reach the threshold value Emin of the minimum reception power as described above, high transmission power is consumed when the transmission power is controlled, and the transmission power of other blocks is reduced. Therefore, the transmission power of the fifth block B5 is set to zero. This allows
The transmission power of the fifth block B5 will be distributed to other blocks. In this case, the non-transmitted subcarriers are regarded as carrier holes, and no modulation symbol is transmitted on the subcarriers. Remaining blocks B2, B3
Regarding B4, B6 and B7, the transmission power control information EB2, EB3, EB4, EB6 and EB7 shown in FIG. 6 respectively.
The transmission power is controlled to increase in accordance with.

As described above, in the orthogonal frequency division multiplexing system of the present invention, continuous subcarriers whose received power falls within a predetermined range are collectively made into a block, and transmission power control is performed for each block. . In this way, the transmission power control is performed for each block in which some subcarriers are collected, so that the storage amount of the control information management table 16a for storing the control information can be reduced and the transmission power control can be performed. The processing amount can be reduced. In addition, since the fluctuation of the received power due to the effect of frequency selective fading is divided into blocks so that they can be regarded as almost equal, the block configuration will be changed to adapt to the change in the channel specific, Efficient transmission power control can be performed. Therefore, the orthogonal frequency division multiplexing system of the present invention can enable high-speed transmission and high-quality transmission.

By the way, the subcarriers may be grouped as a block as follows. It is assumed that the OFDM signal received by the mobile station 2 is received as an envelope as shown in FIG. Number of subcarriers n in this case
Is, for example, 60. Then, as shown in FIG. 4, when the subcarriers of the reception power within the range of the threshold value ΔE are collectively divided into blocks, the number of subcarriers in the first block B1 becomes 10 as shown in FIG. The number of subcarriers in B2 also becomes 10, and the third block B3
5, the number of subcarriers in the fourth block B4 is 15, and the number of subcarriers in the fifth block B5 is 20. In this case, the cumulative value of the probability distribution that the number of carriers exists with respect to the number of carriers is calculated as shown in the chart of FIG.

That is, the block in which the number of carriers is 5 is only the third block B3, and in this case, (the number of blocks / the total number of blocks) is 1/5. Therefore, the cumulative value when the number of carriers is 5 or less is also 1/5. Further, the blocks for which the number of carriers is 10 are the first block B1 and the second block B2, and in this case, (the number of blocks / the total number of blocks) is 2/5. Therefore, the cumulative value when the number of carriers is 10 or less is 1/5 + 2/5 = 3/5. Further, the block in which the number of carriers is 15 is only the fourth block B4, and in this case, (the number of blocks / the total number of blocks) is 1/5. Therefore, the cumulative value when the number of carriers is 15 or less is 1/5 + 2/5 + 1/5 = 4/5. Furthermore, the block in which the number of carriers is 20 is only the fifth block B5, and in this case, (the number of blocks / the total number of blocks) is 1/5. Therefore, the cumulative value when the number of carriers is 20 or less is 1/5 + 2/5 + 1/5 + 1/5 = 5/5. With this cumulative value as a percentage value, the number of carriers (S
When the graph is displayed with the C number) as the horizontal axis, the graph shown in FIG. When the number of carriers whose cumulative value is about 54% is calculated from this graph, the number of subcarriers is about 9. Therefore, 60 subcarriers are grouped into blocks every 9 subcarriers. In this way, the number of subcarriers obtained from the cumulative value of the probability distribution may be a block that is put together. In this case, the number of subcarriers in each block is a fixed value.

Next, FIG. 12 shows a flowchart of the transmission power control process in the orthogonal frequency division multiplexing system according to the embodiment of the present invention. When the transmission power control process shown in FIG. 12 is started and the base station transmits a pilot signal through the control channel (step S1), the mobile station receives this pilot signal (step S10). Next, the received powers of all subcarriers of the OFDM signal in the pilot signal received in step S11 are measured. In step S12, the adjacent subcarriers have a high frequency correlation, and it is possible to consider that the fluctuations in the received power due to the effect of frequency selective fading in the subcarriers within a certain correlation bandwidth are almost equal. Is blocked. That is, subcarriers are divided into blocks by grouping consecutive subcarriers that do not exceed the set threshold value ΔE into blocks. Further, the number of blocks divided in step S13 is detected, and the head sub carry number in each block is determined. Here, the block length may be fixed and re-blocked into a block length having the smallest number of subcarriers combined into a block. Further, by referring to the graph of the number of subcarriers with respect to the cumulative value as shown in FIG. 11, the number of subcarriers having a desired cumulative value may be obtained and reblocked into blocks of the obtained number of subcarriers.

Next, in step S14, the difference between the reception power value of the subcarrier having the minimum reception power in each block and the specified reception power is calculated and used as the transmission power control value. Then, the calculated transmission power control value and step S1
The base station is notified of the control information including the head subcarrier number determined in 3 (step S15). Upon receiving this notification, the base station controls the transmission power of each block based on the control information notified in step S2. That is,
The subcarriers are grouped into several subcarriers up to immediately before the first subcarrier number in the control information, and the transmission power of the subcarriers in each of the blocked subcarriers is set to that of the block in the control information. Control according to the transmission power control information. This makes it possible to control the reception power of the subcarriers of the OFDM signal received by the mobile station so as to be substantially constant even when subjected to frequency selective fading.

In the mobile station 2 of the present invention described above,
A transmission power control unit may be provided in the OFDM modulator 27 similarly to the base station 1, and transmission power control of the OFDM signal may be performed based on the control information obtained by the control unit 26. In this case, the subcarriers are divided into blocks based on the head subcarrier number in the control information, and the transmission power of the subcarriers in the block is controlled according to the transmission power control value corresponding to the block. Note that the transmission power transmitted from the base station 1 is not controlled O
The period in which the FDM-modulated pilot signal is transmitted is
The period is set to sufficiently follow the fluctuation of the received power caused by frequency selective fading in the propagation path.

[0036]

As described above, according to the present invention, the subcarriers are grouped into blocks according to the received power, and the transmission power control is performed for each block. As described above, since the transmission power control is performed for each block in which some subcarriers are collected, it is possible to reduce the control information amount and the transmission power control processing amount and storage amount. become able to. Such transmission power control processing is performed every time a pilot signal is transmitted from the transmission side with a fixed transmission power. Further, as described above, the adjacent subcarriers have a high frequency correlation, and the fluctuations in the received power due to the effect of frequency selective fading on the subcarriers within a certain correlation bandwidth can be considered to be almost equal. Because you can. Therefore, the block configuration becomes adaptive to a specific change in the propagation path, and efficient transmission power control can be performed. Therefore, the orthogonal frequency division multiplexing system of the present invention can enable high-speed transmission and high-quality transmission.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration example of an orthogonal frequency division multiplexing system according to an exemplary embodiment of the present invention.

FIG. 2 is a diagram showing pilot signals in a control channel transmitted from a base station in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

FIG. 3 is a diagram showing an OFDM signal affected by selective fading in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

[Fig. 4] Fig. 4 is a diagram for explaining that the received OFDM signals in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention are grouped into blocks.

[Fig. 5] Fig. 5 is a diagram for explaining another method of collecting received OFDM signals into blocks in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

FIG. 6 is a diagram for explaining transmission power control information of blocks in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

FIG. 7 is an OF transmitted under transmission power control in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.
It is a figure which shows a DM signal.

FIG. 8 is a diagram showing an aspect of transmitting control information in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

FIG. 9 is a diagram showing the number of subcarriers obtained by blocking an OFDM signal affected by selective fading in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

10 is a chart showing the cumulative value of the probability distribution that the number of carriers exists with respect to the number of carriers in the example shown in FIG.

11 is a graph showing a cumulative value of a probability distribution that the number of carriers exists with respect to the number of carriers shown in FIG.

FIG. 12 is a flowchart of transmission power control processing in the orthogonal frequency division multiplexing system according to the exemplary embodiment of the present invention.

FIG. 13 is a diagram showing an OFDM signal transmitted from a base station in a conventional orthogonal frequency division multiplexing system.

FIG. 14 is a diagram showing an OFDM signal affected by selective fading in an orthogonal frequency division multiplexing system.

[Explanation of symbols]

1 base station, 2 mobile station, 10 OFDM modulator, 11
Encoder, 12 symbol modulator, 13 S / P converter, 14 transmission power controller, 15 IFFT section, 16
Control unit, 16a control information management table, 17 OFD
M demodulator, 20 OFDM demodulator, 21 FFT section, 2
2 reception power measurement unit, 23 P / S conversion unit, 24 decoder, 25 symbol demodulation unit, 26 control unit, 27 OF
DM modulator

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[Procedure amendment]

[Submission date] December 14, 2001 (2001.12.
14)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0015

[Correction method] Change

[Correction content]

[0015]

FIG. 1 shows an example of the configuration of an orthogonal frequency division multiplexing system according to an embodiment of the present invention. However, although the base station 1 and one mobile station 2 are shown in FIG. 1, there are many mobile stations, and only the mobile station 2 among them is shown. The mobile station 2 corresponds to the transmitting / receiving device according to the embodiment of the present invention. In FIG. 1, the base station 1 includes an OFDM modulator 10, an OFDM demodulator 17, and a control unit 16 that controls transmission power. This O
The FDM demodulator 17 uses the OFD in the mobile station 2 described later.
The configuration is such that the reception power measuring unit 22 of the M demodulator 20 is omitted. The transmission data is applied to the encoder 11 in the OFDM modulator 10, is subjected to encoding such as error correction encoding and compression encoding, and is symbol-modulated in the symbol modulator 12. In the symbol modulator 12, modulation such as BPSK, QPSK, 16QAM or 64QAM is performed according to the transmission speed and the required transmission quality. The modulation symbol output from the symbol modulator 12 is converted into a parallel number of modulation symbols corresponding to the number of subcarriers in the serial-parallel conversion unit (S / P conversion unit) 13.
As a result, the symbol rate of the modulation symbol output from the S / P converter 13 is reduced to 1 / the number of subcarriers.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0017

[Correction method] Change

[Correction content]

Mobile station 2 capable of receiving this OFDM signal
Includes an OFDM demodulator 20, an OFDM modulator 27, and a control unit 26. This OFDM modulator 27
Has a configuration in which the transmission power control unit 14 of the OFDM modulator 10 in the base station 1 is omitted. The OFDM signal received by the mobile station 2 is a fast Fourier transform unit (FF
In (T) 21, the Fourier transform is applied and decomposed for each subcarrier. The FFT 21 may be a discrete Fourier transform unit (DFT). The reception power of each subcarrier output in parallel from the FFT unit 21 is measured by the reception power measuring unit 22, and the reception power value of each subcarrier is supplied to the control unit 26. The subcarriers output in parallel from the FFT unit 21 are supplied to the parallel-serial conversion unit (P / S conversion unit) 23 via the reception power measurement unit 22, and the modulation symbols of the parallel subcarriers are serialized. Are converted to modulation symbols of. This P / S converter 23
The modulation symbol of the subcarrier output from is demodulated by the symbol demodulation unit 25 to be demodulated data.
In the symbol demodulation unit 25, BPSK, QPSK, 16QAM or 64QAM applied on the transmission side is used.
Demodulation is performed according to the modulation such as. Symbol demodulator 25
The demodulated data output from is subjected to error correction, decompression processing, etc. in the decoder 24 and is decoded into received data and output.

Claims (10)

[Claims] 1. A reception power of a plurality of subcarriers constituting an orthogonal frequency division multiplex signal received by a reception side, which receives an orthogonal frequency division multiplex signal transmitted from a transmission side with a fixed transmission power. According to the value, the blocks are made up of several subcarriers, the number of the subcarrier at a specific position in the block, and the difference information between the received power value and the specified received power in each block are transmitted. To the side, on the transmission side that has received the subcarrier number and the difference information, a plurality of subcarriers forming an orthogonal frequency division multiplexed signal, while dividing into blocks based on the number of the subcarrier The orthogonal frequency is characterized in that the transmission power of the subcarrier of the block is controlled based on the difference information. Number division multiplex system. 2. The orthogonal frequency division according to claim 1, wherein sub-carriers whose received power difference between sub-carriers falls within a predetermined threshold are grouped so as to be divided into the blocks. Multiple systems. 3. When the plurality of subcarriers are divided into the blocks, a block having the smallest number of subcarriers included in the divided blocks is obtained, and the block lengths of all blocks are obtained as the obtained blocks. The orthogonal frequency division multiplexing system according to claim 1, wherein the block length is 4. The number of subcarriers when dividing into blocks is obtained by referring to a table of cumulative values of probability distributions in which the number of subcarriers exists with respect to the number of subcarriers. An orthogonal frequency division multiplexing system as described. 5. For a block whose received power on the receiving side does not reach a predetermined minimum received power value, the transmitting power is distributed to other blocks on the basis of the difference information on the transmitting side. The orthogonal frequency division multiplexing system according to claim 1, wherein: 6. A transmission / reception device capable of transmitting and receiving an orthogonal frequency division multiplex signal, wherein: according to the reception power values of a plurality of subcarriers forming the orthogonal frequency division multiplex signal transmitted with fixed transmission power, Dividing means for grouping the blocks into a number of subcarriers, a subcarrier number at a specific position in each block divided by the dividing means, a received power value in each of the divided blocks, and defined reception And a control unit for obtaining difference information with respect to electric power, wherein control information including the subcarrier number and the difference information is transmitted at a predetermined cycle under the control of the control unit. Characterizing transceiver device. 7. The transmission / reception device according to claim 6, wherein the subcarriers whose difference in received power between the subcarriers falls within a predetermined threshold are grouped to be divided into the blocks. 8. When the plurality of subcarriers are divided into a plurality of blocks, a block having the minimum number of subcarriers included in the divided blocks is obtained, and the block lengths of all the blocks are obtained. 7. The transmission / reception device according to claim 6, wherein the block length is set to the block length. 9. The number of subcarriers when dividing into blocks is obtained by referring to a table of cumulative values of probability distributions in which the number of subcarriers exists with respect to the number of subcarriers. The described transceiver device. 10. For a block whose received power does not reach a predetermined minimum received power value, said control means is
7. The transmitter / receiver according to claim 6, wherein control information is created so that the transmission power of the block is distributed to other blocks.