JP3843870B2 - OFDM communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an OFDM communication apparatus in a digital wireless communication system.
[0002]
[Prior art]
In recent years, communication using orthogonal frequency division multiplexing (hereinafter referred to as OFDM) signals has attracted attention in digital audio broadcasting for mobiles, terrestrial digital television broadcasting, and the like. This is because the OFDM signal has good frequency utilization efficiency, enables high-speed transmission of a large amount of data, and has little characteristic deterioration due to reflected waves. In addition, since the signal waveform has a form close to random noise, it has a feature that it is difficult to interfere with other services.
[0003]
In a conventional OFDM communication apparatus, the received signal is subjected to time axis-frequency axis conversion by FFT means, and a transmission path estimation value is obtained by performing arithmetic processing between a transmission path estimation symbol included in the received signal and a known signal. . Then, the transmission path distortion is compensated by calculating the transmission path estimation value and the information symbol. The received signal whose transmission path distortion is compensated is demodulated and error-corrected by an error correction means to obtain an information bit string which is received data.
[0004]
Also, when transmitting long information, as shown in FIG. 3, by inserting transmission path estimation symbols (shaded portions) at certain intervals in the information symbol, it follows changes in the transmission path response that change from moment to moment. Then, since the transmission efficiency is lowered, as shown in FIG. 4, a transmission path estimation method for adaptively estimating the transmission path response using the received information symbol determination value as a known signal is adopted. Accordingly, even when long information is transmitted or when the time variation of the transmission line response is large, the transmission efficiency is adaptively followed without decreasing the transmission efficiency (Japanese Patent Application No. 11-245098). issue).
[0005]
The preamble in FIG. 3 is a symbol for detecting a symbol synchronization signal in the synchronization process.
[0006]
Hereinafter, such a conventional OFDM communication apparatus will be described with reference to FIG.
[0007]
On the reception side, the reception signal is received and processed as follows.
[0008]
The transmission path receiving unit 1 includes a baseband processing unit 11 and a synchronization unit 12. The adaptive decoding unit 3 includes a transmission path estimation compensation unit 31, an error correction unit 32, and a re-encoding unit 33.
[0009]
The OFDM signal received through the antenna is subjected to normal radio reception processing by the baseband processing means 11 to become a baseband signal. This baseband signal is subjected to A / D conversion after removing unnecessary frequency components by a low-pass filter. The A / D converted received signal is detected by the synchronization means 12 from the transmission path estimation symbol included in the OFDM reception signal and symbol synchronization for the transmission path estimation value, and the carrier frequency deviation is compensated. The received signal after the synchronization processing compensated for the carrier frequency deviation is subjected to time axis-frequency axis conversion in synchronization with symbol synchronization by FFT (Fast Fourier Transform) means 2, and the information symbol assigned to each subcarrier is changed. can get. The information symbol subjected to the FFT operation by the FFT means 2 is sent to the transmission path estimation compensation means 31 together with the enable signal, and when the transmission path estimation symbol detection signal is detected, the known signal and the transmission path estimation symbol are obtained. An initial transmission path estimation value is obtained by performing arithmetic processing. The transmission path estimation compensation means 31 sequentially performs transmission path distortion compensation of information symbols for each OFDM symbol using the initial transmission path estimation value.
[0010]
The information symbols that have been compensated for the transmission path are sequentially sent to the error correction means 32 together with the enable signal to be error-corrected. The error correction means 32 outputs an error-corrected information symbol together with an enable signal. The re-encoding means 33 performs encoding processing, modulation processing, and rearrangement processing on the error-corrected information symbols. The information symbols after error correction re-encoded in this way are sent to the transmission path estimation compensation means 31 together with the enable signal. The transmission path estimation compensation means 31 uses this re-encoded information symbol as a known signal, performs transmission path estimation by performing arithmetic processing with a signal subjected to FFT calculation corresponding to the re-encoded information symbol, Obtain the transmission path estimate. This transmission path estimation value is used as a new transmission path estimation value instead of the initial transmission path estimation value.
[0011]
At this time, the OFDM signal is a multi-carrier scheme, and in order to realize the update using the information symbol of the transmission path estimation value shown above in the multi-carrier scheme in comparison with the single carrier scheme, an FFT operation is performed. The memory for holding information symbols on the frequency axis becomes enormous. In order to minimize the memory for holding the information symbol on the frequency axis that has been subjected to the FFT operation, instead of performing adaptive update of the channel estimation value for each information symbol as shown in FIG. Therefore, it is necessary to adaptively update the channel estimation value at a certain interval.
[0012]
Whether the information symbols output from the FFT means 2 are subject to re-encoded information symbols, which are known signals for calculating the channel estimation value, at what interval, is determined by the maximum of each processing means determined by the modulation method. It was determined by the processing delay.
[0013]
The above will be described with reference to FIG.
[0014]
Assume the number of bits constituting an information symbol as follows.
[0015]
BPSK = 24 bits QPSK = 48 bits 16QAM = 96 bits Further, the Viterbi path memory length of the error correction means 32 is assumed as follows.
[0016]
Assuming the Viterbi path memory length = 96 stages as described above, the information symbols output from the FFT means 2 are converted into the transmission path estimation compensation means 31, the error correction means 32, the re-encoding means 33, and the transmission path estimation compensation means 31. It takes 5 symbols if the modulation scheme is BPSK, 3 symbols if QPSK, and 2 symbols if 16QAM until a transmission path estimation value is calculated. It is assumed that processing delay is zero except for the error correction means 32.
[0017]
The information symbol output from the FFT means 2 is subject to a re-encoded information symbol for making a known signal at what interval, since the maximum processing delay is 5 symbols of BPSK. The target of the encoded information symbol is 5 symbol intervals.
[0018]
As shown in FIG. 9, the FFT symbol count means 5 counts in synchronization with the symbol synchronization signal output from the synchronization means 12, and the count value is 1 for the information symbol output from the FFT means 2, as shown in FIG. The information symbol at the time of is a target of a re-encoded information symbol which is a known signal. Based on the FFT output target symbol detection signal output from the FFT symbol counter means 5, the transmission path estimation compensation means 31 holds the information symbol output from the FFT means 2 when the count value is 1. The re-encoded symbol counting means 6 counts in synchronization with the enable signal output from the re-encoding means 33, and the re-encoded information symbol output from the re-encoding means 33 in synchronization with the enable signal. The re-encoded information symbol when the count value is 1 is set as a target symbol for calculation as a transmission path estimation value. The transmission path estimation compensation means 31 detects the information symbol held by the FFT output target symbol detection signal and the recoding target symbol detection signal by the recoding target symbol detection signal output from the recoding symbol count means 6. The transmission channel estimation compensation means 31 calculates the transmission channel estimation value based on the re-encoded information symbol. The counters of the FFT symbol count means 5 and the re-encoded symbol count means 6 are reset by a transmission path estimation symbol detection signal output from the synchronization means 12.
[0019]
It should be noted that the shorter the update interval of the transmission line estimation value, the stronger the time fluctuation of the transmission line response.
[0020]
[Problems to be solved by the invention]
The conventional OFDM communication apparatus employs a transmission path estimation method that adaptively estimates a transmission path response using a re-encoded information symbol of a received information symbol as a known signal. As a result, even when long information is transmitted or when the time variation of the transmission line response is large, the time variation of the transmission line is adaptively followed without lowering the transmission efficiency.
[0021]
However, in recent years, the standard for changing the modulation scheme of information symbols in a complex manner has been attracting attention. Whether the information symbol that has been subjected to the FFT operation is to be a target of a re-encoded information symbol that is a known signal for calculating a transmission path estimation value is determined by the maximum processing delay of each processing unit determined by the modulation method. Since it is fixed, there is a problem in that the information symbol interval for transmission path estimation takes more than necessary even in a modulation scheme in which the processing delay of each processing means does not take much.
[0022]
The present invention has been made in view of such a point, and even for an OFDM signal composed of a plurality of information symbols composed of a plurality of modulation schemes, it is particularly multivalued by adaptively following the time variation of the transmission path. An object of the present invention is to provide an OFDM communication apparatus capable of improving reception characteristics in a modulation scheme.
[0023]
[Means for Solving the Problems]
In order to achieve the above object, the first invention is a transmission path receiving means for receiving a received signal and outputting a transmission path estimation symbol detection signal, a symbol synchronization signal, and a received signal after synchronization processing. , the transmission path estimation symbol detection signal, the symbol synchronization signal and to determine whether re-encoding flag from the channel estimation value calculation completion signal, re-encoding flag adding means for outputting a first re-coding flag And FFT means for performing FFT conversion on the received signal after the synchronization processing output from the transmission path receiving means in synchronization with the symbol synchronization signal, and outputting the information symbol after the FFT conversion and the first enable signal ; , information symbols after the FFT transformation, the first enable signal, the first re-encoding flag, and the transmission path estimation symbol detection signal is input, the channel estimation Using the information symbols after the FFT transform symbol detection signal is output, or transmitted using information symbols after the FFT transform of when the re-encoding flag means outputs the first re-encoding flag And an adaptive decoding unit that calculates a channel estimation value, outputs a transmission channel estimation value calculation completion signal, and performs channel compensation.
[0024]
According to the first invention as described above, the re-encoding flag adding means sequentially re-encodes the information symbols inputted immediately after the transmission path estimation value calculation completion signal outputted from the adaptive decoding means. Therefore, even if the modulation method changes in a complex manner even in continuous information symbols, the transmission path estimation value can be updated at variable intervals according to the processing delay of each processing means according to the modulation method. The reception characteristics of the multi-level modulation method can be improved.
[0025]
According to a second aspect of the present invention, the adaptive decoding unit includes a channel estimation compensation unit, an error correction unit, and a re-encoding unit, and the channel estimation compensation unit includes the information symbol after the FFT conversion. , The first enable signal , the second re-encoding flag output from the re-encoding means , and the transmission path estimation symbol detection signal are input, and the transmission path estimation symbol and the second A channel estimation value is calculated using the re-encoded information symbol to which the re-encoding flag is added, the channel distortion of the information symbol is compensated using the channel estimation value, and information after channel compensation A second enable signal of the information symbol after the transmission path compensation, and a third re-encoding flag , and the error correction means outputs the information symbol after the transmission path compensation and the second enable signal. signal And the third re-coding flag of the input, and error correction processing on the information symbols after the channel compensation, the information symbols after error correction, a third enable signal information symbols after the error correction, And a fourth re-encoding flag, and the re-encoding means receives the error-corrected information symbol, the third enable signal , and the fourth re-encoding flag, and inputs the error Only the information symbol after error correction to which the re-encoding flag is added to the corrected information symbol is re-encoded, and the re-encoded information symbol and the second re-encoding flag are output . It is characterized by having been comprised.
[0026]
According to the second invention as described above, since the re-encoding process can be performed only for the signal with the re-encoding flag, it is possible to update the transmission path estimation value with low power consumption. it can.
[0027]
A third invention is characterized in that, in the second invention, the error correction means controls the memory capacity for holding the received information compensated for the transmission path distortion by the transmission path quality information inputted from the outside. And
[0028]
According to the third invention as described above, the memory capacity required for error correction is switched according to transmission path quality information input from the outside. Therefore, when the transmission line quality is good, the processing delay can be minimized by switching the memory capacity necessary for the error correction process to the minimum, and when the transmission line quality is bad, the error correction process is performed. The required memory capacity can be maximized and the error correction processing capability can be enhanced.
[0029]
In a fourth aspect based on the second aspect , the error correction means controls the memory capacity for holding the reception information compensated for the transmission path distortion based on the transmission path quality information detected from the received signal. Features.
[0030]
According to the fourth invention as described above, the memory capacity necessary for error correction is switched based on the transmission path quality information detected from the received signal. Therefore, when the transmission line quality is good, the processing delay can be minimized by switching the memory capacity necessary for the error correction process to the minimum, and when the transmission line quality is bad, the error correction process is performed. The required memory capacity can be maximized and the error correction processing capability can be enhanced.
[0031]
A fifth invention is characterized in that, in the second invention, the error correction means controls a memory capacity for holding received information whose transmission path distortion is compensated by modulation method information inputted from outside. To do.
[0032]
According to the fifth invention as described above, the memory capacity necessary for error correction is switched by the modulation method information input from the outside. Therefore, when the modulation method is not a multi-level method, the processing delay can be minimized by switching the memory capacity required for error correction processing to the minimum. When the modulation method is a multi-level method Can maximize the memory capacity required for error correction processing and enhance the error correction processing capability.
[0033]
According to a sixth invention, in the second invention, the error correction means controls the memory capacity for holding the received information in which the transmission path distortion is compensated by the modulation scheme information added to the received signal. And
[0034]
According to the sixth invention as described above, the memory capacity required for error correction is switched by the modulation scheme information added to the received signal. Therefore, when the modulation method is not a multi-level method, the processing delay can be minimized by switching the memory capacity required for error correction processing to the minimum. When the modulation method is a multi-level method Can maximize the memory capacity required for error correction processing and enhance the error correction processing capability.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
The OFDM communication apparatus according to the first embodiment of the present invention will be described with reference to FIG.
[0036]
The transmission path receiving unit 1 includes a baseband processing unit 11 and a synchronization unit 12. The adaptive decoding unit 3 includes a transmission path estimation compensation unit 31, an error correction unit 32, and a re-encoding unit 33.
[0037]
The OFDM signal received through the antenna is subjected to normal radio reception processing by the baseband processing means 11 to become a baseband signal. This baseband signal is subjected to A / D conversion after removing unnecessary frequency components by a low-pass filter.
[0038]
The A / D converted received signal is detected by the synchronization means 12 from the transmission path estimation symbol included in the OFDM reception signal and symbol synchronization to compensate for the carrier frequency deviation. The received signal after the synchronization process compensated for the carrier frequency shift is subjected to time axis-frequency axis conversion in synchronization with symbol synchronization by FFT (Fast Fourier Transform) means 2 to obtain information symbols assigned to each subcarrier. It is done.
[0039]
The signal subjected to the FFT operation by the FFT means 2 is sent together with the enable signal to the transmission path estimation compensation means 31. When the transmission path estimation symbol detection signal is detected, the known signal and the transmission path estimation symbol are calculated. The first transmission path estimation value is obtained by processing. The transmission path estimation compensation means 31 sequentially performs transmission path distortion compensation of information symbols for each information symbol using the first transmission path estimation value.
[0040]
The information symbols that have been compensated for the transmission path are sequentially sent to the error correction means 32 together with the enable signal to be error-corrected. From the error correction means 32, an information symbol error-corrected for each unit to be encoded is output together with an enable signal. At this time, as shown in FIG. 1, the re-encoding flag adding means 4 re-synchronizes the information symbol immediately after the transmission path estimation symbol in which the transmission path estimation symbol detection signal is detected in synchronization with symbol synchronization. Add an encoding flag. If the re-encoding flag is added to the information symbol, the transmission path estimation compensating unit 31 and the error correcting unit 32 output the re-encoding flag together with the information symbol and the enable signal. The information symbol after error correction is sent to the re-encoding means 33 together with the enable signal and the re-encoding flag. In the re-encoding unit 33, only the error-corrected information symbol to which the re-encoding flag is added is subjected to encoding processing, modulation processing, and rearrangement processing. A re-encoded information symbol used as a known signal output from the re-encoding unit 33 is sent to the transmission path estimation and compensation unit 31. The transmission path estimation compensation means 31 uses this re-encoded information symbol as a known signal, performs transmission path estimation by performing arithmetic processing with the information symbol that has been subjected to the FFT operation corresponding to the re-encoded information symbol, and performs transmission path estimation. Find the value. This transmission path estimation value is used as a new transmission path estimation value instead of the initial transmission path estimation value.
[0041]
At this time, the transmission path estimation compensation means 31 outputs a transmission path estimation value calculation completion signal notifying that the update as a new transmission path estimation value has been completed with respect to the initial transmission path estimation value, and the re-encoding The encoding flag adding means 4 adds a re-encoding flag to the information symbol output from the FFT means 2 immediately after the transmission path estimated value calculation completion signal is output. The above procedure is repeated until a transmission path estimation symbol detection signal is detected. When a transmission path estimation symbol detection signal is detected, a transmission path estimation value is obtained by performing arithmetic processing on the known signal and the detected transmission path estimation symbol, and transmission path compensation is performed.
[0042]
The above will be specifically described with reference to FIG.
[0043]
Assume the number of bits making up the OFDM symbol as follows.
[0044]
BPSK = 24 bits QPSK = 48 bits 16QAM = 96 bits Further, the Viterbi path memory length of the error correction means 32 is assumed as follows.
[0045]
Assuming the Viterbi path memory length = 96 stages as described above, the information symbols output from the FFT means 2 are converted into the transmission path estimation compensation means 31, the error correction means 32, the re-encoding means 33, and the transmission path estimation compensation means 31. It takes 5 symbols if the modulation scheme is BPSK, 3 symbols if QPSK, and 2 symbols if 16QAM until a transmission path estimation value is calculated. It is assumed that processing delay is zero except for the error correction means 32.
[0046]
The information symbols output from the FFT means 2 are subject to re-encoded information symbols for making known signals at a certain interval. As a result, 5 BPSK symbols, 3 QPSK symbols, and 16 QAM symbols are 2 symbols. The target of re-encoded information bits can be changed according to the modulation scheme.
[0047]
As the multi-level modulation method is used as shown in FIG. 5, the number of information bits occupying per information symbol increases, so that the transmission path estimation value calculation interval is shortened and the transmission path response is more resistant to temporal variations. As a result, the reception performance can be improved as the multi-level modulation system is not particularly resistant to transmission path distortion.
[0048]
(Embodiment 2)
An OFDM communication apparatus according to the second embodiment of the present invention will be described with reference to FIG.
[0049]
The baseband processing unit 11, the synchronization unit 12, the FFT unit 2, the transmission path estimation compensation unit 31, and the re-encoding unit 33 have the same functions as those in the first embodiment. The error correction means 32 makes the capacity of the memory for storing received data used for error correction variable by an external memory switching signal.
[0050]
More specifically, when the error correction means 32 performs Viterbi error correction by the memory switching signal, the Viterbi path memory length is switched from 96 to 48.
[0051]
A memory switching signal input from the outside can be used as transmission path quality information indicating the state of the transmission path. When the transmission path quality is good, the power consumption and processing delay can be minimized by switching the memory capacity required for error correction processing to the minimum. When the transmission path quality is poor, error correction is performed. The memory capacity required for processing can be maximized and the error correction processing capability can be enhanced. As described above, the processing delay of the error correction unit 32 changes depending on the state of the transmission path even in the same modulation method. However, the re-encoding flag addition unit 4 described in the first embodiment changes the delay processing by switching the memory capacity. The calculation of the transmission path estimation value can follow adaptively.
[0052]
Further, the transmission path quality information may be detected internally. For example, the transmission path quality information may be obtained by quantifying the peak signal of the received signal when the synchronization means 12 detects the symbol synchronization and the constellation variation of the transmission path estimation compensation means 31. This can speed up the memory switching.
[0053]
Further, a memory switching signal input from the outside can be used as modulation scheme information representing a modulation scheme. As shown in FIG. 7, the error rate with respect to the transmission path distortion of the input signal of each modulation method is strong in BPSK and becomes weaker as multi-level modulation such as 64QAM is performed.
[0054]
Therefore, when the modulation method is not a multi-value method, the power consumption and the processing delay can be minimized by switching the memory capacity necessary for error correction processing to the minimum. In the case of this method, the memory capacity necessary for error correction processing can be maximized and the error correction processing capability can be enhanced.
[0055]
In addition, although the processing delay of the error correction unit 32 changes depending on the modulation method as described above, the transmission path estimation value is calculated by the re-encoding flag addition unit 4 described in the first embodiment to the change of the delay processing due to the memory capacity switching. Can follow adaptively.
[0056]
The modulation scheme information may be detected from internal reception data. For example, if it is known in advance which bit of which symbol of the received data corresponds to it, the memory of the error correction means 32 may be switched using that data. As a result, the memory can be switched quickly.
[0057]
【The invention's effect】
As described above, a radio receiving means for receiving a received signal and outputting a transmission path estimation symbol detection signal, a symbol synchronization signal, and a reception signal after synchronization processing, the transmission path estimation symbol detection signal, and the symbol Re-encoding flag adding means for determining the presence / absence of a re-encoding flag from a synchronization signal and a transmission path estimation value calculation completion signal, and outputting the re-encoding flag; and the received signal after the synchronization process as the symbol synchronization signal FFT means for performing FFT conversion in synchronization and outputting information symbol and enable signal after FFT conversion, the information symbol after FFT conversion, the enable signal, the re-encoding flag, and the transmission path estimation An information symbol to which a symbol detection signal is input, the information symbol detected by the transmission path estimation symbol is added, and a re-encoding flag is added And an adaptive decoding unit that outputs a transmission channel estimation value calculation signal, outputs the transmission channel estimation value calculation completion signal, and performs transmission channel compensation. By adding a re-encoding flag sequentially to the information symbols input immediately after the transmission path estimation value calculation completion signal output from the adaptive demodulating means, the modulation system changes in a complicated manner even in continuous information symbols. However, it is possible to update the channel estimation value at variable intervals according to the processing delay of each processing means according to the modulation method, and in particular, it is possible to improve the reception characteristics of the multi-level modulation method.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of an OFDM communication apparatus according to the present invention. FIG. 2 is a block diagram showing a second embodiment of the OFDM communication apparatus according to the present invention. FIG. 4 is a diagram illustrating transmission path compensation using an error correction output as a known signal. FIG. 5 is a timing diagram illustrating transmission path compensation using the error correction output as a known signal according to the first embodiment of the present invention. FIG. 7 is a timing diagram showing a transmission path compensation value calculation interval according to the modulation scheme of the first embodiment of the present invention. FIG. 7 is a diagram showing a symbol error rate of each modulation scheme in transmission path distortion. FIG. 9 is a block diagram illustrating a conventional example of a communication apparatus. FIG. 9 is a timing diagram illustrating transmission path compensation using the error correction output of the conventional example according to the present invention as a known signal. Timing diagram illustrating the sending passage compensation value calculation interval [Description of symbols]
DESCRIPTION OF SYMBOLS 1 Transmission path receiving means 2 FFT means 3 Adaptive decoding means 4 Recoding flag addition means 5 FFT symbol counting means 6 Recoding symbol count means 11 Baseband processing means 12 Synchronization means 31 Transmission path estimation compensation means 32 Error correction means 33 Re-encoding means

Claims (6)

Transmission path receiving means for receiving a received signal and outputting a transmission path estimation symbol detection signal, a symbol synchronization signal, and a received signal after synchronization processing;
It said transmission path estimation symbol detection signal, the symbol synchronization signal and to determine whether re-encoding flag from the channel estimation value calculation completion signal, and re-encoding flag adding means for outputting a first re-coding flag ,
FFT means for performing FFT conversion on the received signal after the synchronization processing output from the transmission path receiving means in synchronization with the symbol synchronization signal, and outputting an FFT-converted information symbol and a first enable signal ;
The information symbol after the FFT conversion, the first enable signal , the first re-encoding flag , and the transmission path estimation symbol detection signal are input, and the transmission path estimation symbol detection signal is output. Calculating a channel estimation value using the information symbol after FFT conversion , or using the information symbol after FFT conversion when the re-encoding flag means outputs the first re-encoding flag , An OFDM communication apparatus comprising: adaptive decoding means for outputting a transmission line estimation value calculation completion signal and performing transmission line compensation. The adaptive decoding means comprises a channel estimation compensation means, an error correction means, and a re-encoding means,
The transmission path estimation compensation means includes an information symbol after the FFT conversion, the first enable signal , a second re-encoding flag output from the re-encoding means , and the transmission path estimation symbol detection signal. A transmission channel estimation value is calculated using the input channel estimation symbol and the re-encoded information symbol to which the second re-encoding flag is added, and information is transmitted using the transmission channel estimation value. Compensate the transmission path distortion of the symbol, and output the information symbol after transmission path compensation, the second enable signal of the information symbol after transmission path compensation, and the third re-encoding flag ,
The error correction means inputs the information symbol after the transmission path compensation, the second enable signal , and the third re-encoding flag , and performs error correction processing on the information symbol after the transmission path compensation. Outputting an error corrected information symbol, a third enable signal of the error corrected information symbol, and a fourth re-encoding flag ,
The re-encoding means inputs the error-corrected information symbol, the third enable signal , and the fourth re-encoding flag , and sets a re-encoding flag for the error-corrected information symbol. 2. The apparatus according to claim 1, wherein only the added information symbol after error correction is re-encoded, and the re-encoded information symbol and the second re-encoding flag are output. OFDM communication apparatus. 3. The OFDM communication apparatus according to claim 2 , wherein the error correction unit controls a memory capacity for holding reception information in which transmission path distortion is compensated by transmission path quality information input from the outside. 3. The OFDM communication apparatus according to claim 2 , wherein the error correction unit controls a memory capacity for holding reception information in which transmission path distortion is compensated by transmission path quality information detected from a reception signal. 3. The OFDM communication apparatus according to claim 2 , wherein the error correction unit controls a memory capacity for holding reception information in which transmission path distortion is compensated by modulation scheme information input from the outside. 3. The OFDM communication apparatus according to claim 2 , wherein the error correction unit controls a memory capacity for holding reception information in which transmission path distortion is compensated based on modulation scheme information detected from a reception signal.

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