JP2004072251A - OFDM communication device - Google Patents

Abstract

An object of the present invention is to prevent inappropriate transmission path compensation and prevent reception characteristics from being significantly degraded.
As an OFDM communication apparatus, a transmission unit includes a quality determination information addition unit that adds quality determination information to information to be transmitted, and a reception unit receives a transmission path using a transmission path estimation unit and a transmission path estimation value. A transmission path compensator for compensating for transmission path distortion of the signal, an error correction section for performing error correction processing on the signal in which the transmission path distortion has been compensated, and an error correction processing based on the quality determination information. An error detection unit that performs error detection and outputs an error detection signal indicating the presence or absence of an error, and a re-encoding unit that performs re-encoding processing on the signal that has been subjected to the error correction processing. The channel estimation unit obtains a channel estimation value based on the pilot symbol, and performs channel estimation based on the re-encoded signal, and only when the error detection signal indicates that there is no error, Are output instead of those based on pilot symbols.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a communication device that transmits and receives an orthogonal frequency multiplexed signal (hereinafter, referred to as an orthogonal frequency multiplexing (OFDM) signal).
[0002]
[Prior art]
2. Description of the Related Art In recent years, communication using OFDM signals has attracted attention in digital audio broadcasting for mobile objects, terrestrial digital television broadcasting, and the like. This is because the OFDM signal has characteristics that the frequency utilization efficiency is good, a large amount of data can be transmitted at high speed, and the signal is hardly affected by the reflected wave. Since the OFDM signal has a signal waveform that is close to random noise, it also has a feature that it is difficult to cause interference in other services. Further, the OFDM signal is adopted in standards such as IEEE802.11a, and is used not only for broadcasting but also for two-way communication.
[0003]
2. Description of the Related Art A conventional general OFDM communication apparatus performs FFT (fast Fourier transform) operation on a received signal to perform time-axis to frequency-axis conversion, and performs complex multiplication between a pilot symbol included in the received signal and a known signal. As a result, a frequency response estimate of the transmission path is obtained. Then, transmission path distortion is compensated for by complex multiplication of the frequency response estimation value and the received information OFDM symbol. The received signal in which the transmission line distortion has been compensated is demodulated and error-corrected to obtain an information bit sequence as received data.
[0004]
FIG. 9 is an explanatory diagram showing an example of a position where a pilot symbol is inserted. FIG. 10 is an explanatory diagram of adaptive estimation of a channel response. As shown in FIG. 9, when transmitting long information, pilot symbols for channel response estimation are inserted at regular intervals between information OFDM symbols. Then, the transmission line distortion can be compensated by following the ever-changing change of the transmission line response, but the information transmission efficiency decreases.
[0005]
Therefore, as shown in FIG. 10, there is known a transmission channel estimation method for adaptively estimating a transmission channel response using a determination value of a received information signal as a known signal. That is, the first to n-th information OFDM symbols are compensated by the transmission path response X estimated using the pilot symbols. The (n + 1) -th to (2n) -th information OFDM symbols are compensated for by the channel response Y estimated using the first to n-th information OFDM symbols. The (2n + 1) th to 3nth information OFDM symbols are compensated by the channel response Z estimated using the (n + 1) th to 2nth information OFDM symbols.
[0006]
FIG. 11 is a block diagram showing a configuration of a conventional OFDM communication device. The OFDM communication device in FIG. 11 includes a switch 2, a receiving unit 910, and a transmitting unit 940. The receiving section 910 includes a radio receiving section 911, a synchronizing section 912, an FFT section 913, a transmission path estimation / compensation section 915, a residual position error estimation / compensation section 921, an error correction section 922, and a re-encoding section 925. It has. The transmission channel estimation and compensation unit 915 includes a transmission channel compensation unit 916 and a transmission channel estimation unit 917. The transmission unit 940 includes an encoding unit 942, an inverse fast fourier transform (IFFT) unit 943, and a wireless transmission unit 944. The switch 2 is controlled so as to connect the wireless transmitting unit 944 and the antenna 4 during transmission, and to connect the wireless receiving unit 911 and the antenna 4 during reception.
[0007]
The transmitting section 940 will be described. Encoding section 942 performs digital modulation processing on information SD to be transmitted, and outputs modulated signal SF to IFFT section 943. IFFT section 943 performs IFFT operation on modulated signal SF, performs D / A conversion on the obtained OFDM signal, and outputs the result to wireless transmission section 944. Radio transmitting section 944 performs normal radio transmission processing such as frequency conversion on baseband signal SS output from IFFT section 943, and transmits the result via switch 2 and antenna 4.
[0008]
The receiving unit 910 will be described. The OFDM signal received by the antenna 4 is input to the wireless reception unit 911 via the switch 2. Radio reception section 911 performs a normal radio reception process on this signal to obtain a baseband signal. Radio receiving section 911 removes unnecessary frequency components from the baseband signal, further performs A / D conversion, and outputs obtained reception signal RR to synchronization section 912.
[0009]
The synchronization section 912 detects a preamble or the like included in the received signal RR, generates a symbol synchronization signal SY, and outputs it to the FFT section 913. Further, synchronization section 912 compensates for a carrier frequency error, and outputs the obtained compensated reception signal RH to FFT section 913.
[0010]
The FFT section 913 performs time-axis to frequency-axis conversion by synchronizing symbols with the compensated reception signal RH, thereby performing time-axis / frequency-axis conversion to obtain a signal RF assigned to each subcarrier. FFT section 913 outputs obtained signal RF to transmission path compensating section 916 and transmission path estimating section 917.
[0011]
The transmission channel estimation unit 917 stores the signal RF, estimates a transmission channel response based on the signal RF, and outputs the obtained value to the transmission channel compensation unit 916 as a transmission channel estimation value PE. The transmission path compensator 916 sequentially performs transmission path distortion compensation of the information OFDM symbol included in the signal RF for each symbol using the transmission path estimation value PE, and obtains the obtained signal RP in which the transmission path distortion has been compensated. Output to the phase error estimation compensation unit 921.
[0012]
The residual phase error estimation / compensation unit 921 estimates the residual phase error by performing delay detection between adjacent pilot symbols included in the signal RP, and performs residual phase error compensation based on the estimated residual phase error. . The residual phase error estimation / compensation unit 921 outputs the obtained signal RC after the residual phase error compensation to the error correction unit 922.
[0013]
The error correction unit 922 performs error correction on the signal RC, and outputs an error-corrected information bit sequence RD for each channel-coded unit as an error-corrected signal.
[0014]
The error-corrected information bit sequence RD is periodically input to the re-encoding unit 925. The re-encoding unit 925 re-encodes the error-corrected information bit sequence RD by performing a transmission line encoding process, a modulation process, and a rearrangement process, and transmits the obtained re-encoded signal RE to a transmission line Output to the estimation unit 917.
[0015]
First, the transmission path estimating section 917 performs complex multiplication of the received pilot symbol and a predetermined signal, and outputs the obtained result to the transmission path compensating section 916 as a transmission path estimated value PE. Thereafter, the transmission path estimating section 917 obtains the correlation between the stored signal RF and the corresponding re-encoded signal RE output from the re-encoding section 925 by complex multiplication, and performs transmission path estimation. .
[0016]
When the channel estimation unit 917 obtains the channel estimation value based on the re-encoded signal RE, the channel estimation unit 917 uses the channel estimation value as a new channel estimation value PE instead of the channel estimation value based on the pilot symbol. Output.
[0017]
As described above, in the OFDM communication apparatus of FIG. 11, a transmission path estimation method of adaptively estimating a transmission path response using a received and error-corrected information bit re-encoded signal RE as a known signal is used. Has been adopted. Thereby, even when transmitting long information, the transmission efficiency is not reduced, and even when the time variation of the transmission path response is large, the transmission path distortion is adaptively followed to reduce the transmission path distortion. I was trying to compensate.
[0018]
[Problems to be solved by the invention]
However, if there is an error in the error-corrected information bit itself due to the influence of the transmission path distortion, re-encoding processing is performed using the erroneous information bit, and a transmission path compensation value is calculated. Thus, the transmission path is compensated. In such a case, there has been a problem that the transmission path compensation cannot be appropriately performed, and the subsequent reception characteristics are greatly deteriorated.
[0019]
SUMMARY OF THE INVENTION It is an object of the present invention to prevent inappropriate channel compensation by preventing estimation of a channel response based on a signal including an error, and to prevent reception characteristics from being significantly degraded.
[0020]
Another object of the present invention is to reduce power consumption of an OFDM communication device.
[0021]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 comprises a transmitting unit for transmitting an orthogonal frequency division multiplexing (OFDM) signal for transmitting information by a plurality of subcarriers, and a received OFDM signal. An OFDM communication device comprising: a receiving unit that processes quality information; and the transmitting unit includes a quality determination information adding unit that adds quality determination information to information to be transmitted. A FFT (Fast Fourier Transform) process for performing an FFT (Fast Fourier Transform) process on an OFDM signal converted to a baseband signal, and a transmission channel estimation for storing a signal output from the FFT unit and obtaining and outputting a transmission channel estimation value. And an FFT unit using the transmission path estimation value. A transmission path compensating section for compensating for transmission path distortion for an output signal, and outputting the signal; an error correction section for performing error correction processing on the signal in which the transmission path distortion is compensated, and outputting the quality determination information; An error detection unit that performs error detection on the error-corrected signal and outputs an error detection signal indicating the presence or absence of an error, and performs a re-encoding process on the error-corrected signal. And a re-encoding unit for outputting, the transmission path estimation unit obtains and outputs the transmission path estimation value based on pilot symbols included in a signal output by the FFT unit, and The stored signal, corresponding to this, performs a transmission path estimation based on the re-encoded signal output by the re-encoding unit, and when the error detection signal indicates that there is no error, The corresponding re-code A transmission path estimation value based on the obtained signal is output in place of the transmission path estimation value based on the pilot symbol, and when the error detection signal indicates that there is an error, the corresponding re-encoded signal is output. It does not output the transmission path estimation value based on the signal.
[0022]
According to the first aspect of the present invention, based on the quality judgment information, error detection is performed on an error-corrected signal, and if no error is detected, a transmission path estimation value based on the re-encoded signal is calculated. To compensate for transmission line distortion. Since the transmission line distortion is not inappropriately compensated for by using an erroneous transmission channel estimation value based on the re-encoded signal including the error, it is possible to prevent the reception characteristics from being significantly deteriorated.
[0023]
According to a second aspect of the present invention, in the OFDM communication apparatus according to the first aspect, the quality determination information adding unit adds the quality determination information for each information OFDM symbol.
[0024]
According to the second aspect of the present invention, error detection can be performed in units of symbols, and a retransmission request can be immediately made when an error is detected.
[0025]
According to a third aspect of the present invention, in the OFDM communication apparatus according to the second aspect, the quality determination information is a bit indicating a parity of information bits in the same symbol.
[0026]
According to a fourth aspect of the present invention, in the OFDM communication apparatus according to the first aspect, the quality determination information is a predetermined pattern of a plurality of bits.
[0027]
According to a fifth aspect of the present invention, in the OFDM communication apparatus according to the first aspect, at least one of the FFT unit, the transmission path estimation unit, the transmission path compensation unit, the error correction unit, and the error detection unit is provided. And a clock control unit that supplies a clock, stops the clock supply when the error detection signal indicates that there is an error, and restarts the clock supply when the receiving unit receives a predetermined signal. Things.
[0028]
According to the fifth aspect of the present invention, when an error is detected and a retransmission request is made, components that do not need to operate until a signal corresponding to the error is received can be stopped. Therefore, power consumption can be suppressed.
[0029]
According to a sixth aspect of the present invention, in the OFDM communication apparatus according to the fifth aspect, the clock control unit determines whether to stop supplying the clock in accordance with the type of information being received. Things.
[0030]
According to the invention of claim 6, it is possible to stop the supply of the clock only in the case of information that requires a retransmission request.
[0031]
According to a seventh aspect of the present invention, in the OFDM communication apparatus according to the first aspect, a transmission line distortion amount is calculated and output based on a signal point arrangement of the information signal in which the transmission line distortion is compensated. A detection unit is further provided, and the quality judgment information adding unit determines whether to add the quality judgment information according to the transmission path distortion amount.
[0032]
According to the invention of claim 7, when the transmission path distortion is small, the quality determination information is not added, so that the transmission efficiency is not reduced. If the transmission path distortion is large, the quality determination information is added, so that the reception characteristics can be improved.
[0033]
The invention according to claim 8 is the OFDM communication apparatus according to claim 1, further comprising a power detection unit that obtains and outputs the power of the OFDM signal converted to the baseband signal, and the quality determination information addition unit. Determines whether to add the quality judgment information according to the power.
[0034]
According to the invention of claim 8, when the power of the OFDM signal is large, the quality determination information is not added, so that the transmission efficiency is not reduced. When the power of the OFDM signal is low, the quality determination information is added, so that the reception characteristics can be improved.
[0035]
In the ninth aspect of the present invention, in the OFDM communication apparatus according to the first aspect, the quality determination information adding unit determines whether to add the quality determination information according to a signal indicating a type of information to be transmitted. Is to determine.
[0036]
According to the ninth aspect, when the type of information to be transmitted is acceptable even if the bit error rate is relatively large, the quality determination information is not added, so that the transmission efficiency is not reduced. When the type of information to be transmitted is a type that requires a low bit error rate, the quality determination information is added, so that the reception characteristics can be improved.
[0037]
According to a tenth aspect of the present invention, in the OFDM communication apparatus according to the first aspect, the quality determination information adding unit determines whether to add the quality determination information according to a signal indicating a modulation scheme of the subcarrier. Is to determine.
[0038]
According to the tenth aspect, when the modulation method of the subcarrier has a relatively large allowable transmission path distortion, the quality determination information is not added, so that the transmission efficiency is not reduced. Further, when the allowable transmission line distortion is relatively small as in the case of multi-level modulation, the reception characteristics can be improved by adding the quality judgment information.
[0039]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0040]
(1st Embodiment)
FIG. 1 is a block diagram of an OFDM communication device according to the first embodiment of the present invention. The OFDM communication device in FIG. 1 includes a switch 2, a receiving unit 10, and a transmitting unit 40. The receiving unit 10 includes a radio receiving unit 11, a synchronizing unit 12, an FFT unit 13, a transmission path estimation compensation unit 15, a residual position error estimation compensation unit 21, an error correction unit 22, a re-encoding unit 25, , A symbol error detection unit 26 and a clock control unit 31. The transmission channel estimation compensator 15 includes a transmission channel compensator 16 and a transmission channel estimator 17. The transmission section 40 includes a quality determination information addition section 41, an encoding section 42, an inverse fast fourier transform (IFFT) section 43, and a wireless transmission section 44. The switch 2 is controlled so as to connect the radio transmission unit 44 and the antenna 4 during transmission, and to connect the radio reception unit 11 and the antenna 4 during reception.
[0041]
The transmitting unit 40 will be described. The quality judgment information adding unit 41 adds the quality judgment information to the information SD to be transmitted, and outputs the obtained signal SA to the encoding unit 42. FIG. 2 is an explanatory diagram of the addition of the quality determination information. 2, the numbers 1, 2,..., 3n + 1 indicate information OFDM symbol numbers. Although only the first information OFDM symbol is shown in detail, the same applies to symbols other than other pilot symbols.
[0042]
As shown in FIG. 2, the quality judgment information adding section 41 adds a parity bit as quality judgment information to information bits to be transmitted in each information OFDM symbol. The parity bit is an even parity bit that becomes “1” when the number of bits “1” included in the information bit is even, or an odd number of bits “1” included in the information bit. Any of odd parity bits which become "1" in some cases may be used. If an even parity bit or an odd parity bit is used as the quality determination information, only one bit needs to be added for each information OFDM symbol, so that transmission efficiency hardly decreases.
[0043]
As the quality determination information, a known signal of a plurality of bits may be used. That is, in place of the parity bit, for example, a 2-bit known signal, one of “00”, “01”, “10”, and “11” may be used. Further, the quality judgment information may be added not for each information OFDM symbol but for each of a plurality of information OFDM symbols.
[0044]
What kind of information is used as the quality determination information may be determined in advance between the transmitting side and the receiving side OFDM communication apparatus, or for example, by a control signal TMCC (transmission and multiplexing configuration control) indicating a transmission parameter. Alternatively, the reception side OFDM communication apparatus may be notified of whether or not the quality determination information has been added and the type of signal used as the quality determination information.
[0045]
The encoding unit 42 performs digital modulation processing on the signal SA output from the quality determination information addition unit 41 by a method such as, for example, quadrature phase shift keying (QPSK) or quadrature amplitude modulation (QAM), and modulates the modulated signal. The SF is output to the IFFT unit 43.
[0046]
IFFT section 43 performs an IFFT operation on modulated signal SF output from encoding section 42, performs D / A conversion on the obtained OFDM signal, and outputs the result to wireless transmission section 44. The wireless transmission unit 44 performs normal wireless transmission processing such as frequency conversion on the baseband signal SS output from the IFFT unit 43 and transmits the baseband signal SS via the switch 2 and the antenna 4.
[0047]
The receiving unit 10 will be described. The OFDM signal received by the antenna 4 is input to the wireless receiving unit 11 via the switch 2. The wireless receiving unit 11 performs a normal wireless receiving process such as converting the frequency of the signal to obtain a baseband signal. The radio reception unit 11 removes unnecessary frequency components from the baseband signal using a low-pass filter, performs A / D conversion, and outputs the obtained reception signal RR to the synchronization unit 12.
[0048]
The synchronization unit 12 detects a preamble and the like included in the A / D-converted reception signal RR output by the radio reception unit 11, generates a symbol synchronization signal SY, and outputs the symbol synchronization signal SY to the FFT unit 13. Further, synchronization section 12 compensates for an error in the carrier frequency, and outputs the obtained compensated reception signal RH to FFT section 13.
[0049]
The clock control unit 31 includes an FFT unit 13, a transmission line compensation unit 16, a transmission line estimation unit 17, a residual position error estimation and compensation unit 21, an error correction unit 22, and a symbol error detection unit 26 (hereinafter, these will be referred to as the FFT unit 13 The clock CC is supplied to the following processing unit.
[0050]
The FFT unit 13 performs a time axis-frequency axis conversion by synchronizing a symbol with the compensated reception signal RH to perform a time axis-frequency axis conversion, and obtains a signal RF assigned to each subcarrier. The FFT unit 13 outputs the obtained signal RF to the transmission path compensation unit 16 and the transmission path estimation unit 17.
[0051]
The transmission channel estimation unit 17 stores the signal RF, estimates a transmission channel response based on the signal RF, and outputs the obtained value to the transmission channel compensation unit 16 as a transmission channel estimation value PE. The transmission path compensator 16 sequentially performs compensation (transmission path compensation) of the transmission path distortion of the information OFDM symbol included in the signal RF for each symbol using the transmission path estimation value PE, and compensates for the obtained transmission path distortion. The resulting signal RP is output to the residual phase error estimation / compensation unit 21.
[0052]
The residual phase error estimation / compensation unit 21 estimates the residual phase error by performing differential detection between adjacent pilot symbols included in the signal RP whose transmission path distortion has been compensated. The residual phase error refers to an error of the carrier frequency that cannot be compensated by the synchronization unit 12. Based on the estimated residual phase error, residual phase error estimation / compensation section 21 performs residual phase error compensation on all subcarriers for pilot symbols and subsequent information OFDM symbols. The residual phase error estimation / compensation unit 21 outputs the obtained signal RC after the residual phase error compensation to the error correction unit 22.
[0053]
The error correction unit 22 performs error correction on the signal RC after the residual phase error compensation, and outputs an error-corrected information bit sequence RD for each channel-encoded unit as an error-corrected signal.
[0054]
The symbol error detection unit 26 performs error detection on the information bit string RD whose error has been corrected, and outputs an error detection signal ES indicating the presence or absence of an error to the transmission path estimation unit 17. At this time, the symbol error detection unit 26 performs error detection using the quality determination information for each information OFDM symbol. What kind of information is used as the quality determination information is determined in advance between the transmitting side and the receiving side OFDM communication apparatus, or the symbol error detecting unit 26 has a control signal indicating a transmission parameter, etc. It is assumed that the type of signal used as quality determination information has been notified from the OFDM communication apparatus on the transmission side.
[0055]
For example, when an even parity bit is used as the quality determination information, the symbol error detection unit 26 calculates an exclusive OR of the information bit sequence of the information OFDM symbol, and if the result does not match the even parity bit, no error is detected. It is determined that an error has been detected. When the odd parity bit is used as the quality judgment information, an exclusive OR of the information bit sequence of the information OFDM symbol is obtained. If the result matches the odd parity bit, it is determined that no error has been detected. Judge that it was done. Also, when a known signal of a plurality of bits is used as the quality determination information, if the quality determination information of the information OFDM symbol matches the known signal, it is determined that no error has been detected, and if they do not match, it is determined that an error has been detected.
[0056]
The error-corrected information bit sequence RD is input to the re-encoding unit 25 periodically. The re-encoding unit 25 re-encodes the error-corrected information bit sequence RD by performing a transmission line encoding process, a modulation process, and a rearrangement process, and transmits the obtained re-encoded signal RE to a transmission line Output to the estimation unit 17.
[0057]
The transmission path estimating unit 17 first performs complex multiplication of the received pilot symbol and a predetermined signal, and outputs the obtained result to the transmission path compensating unit 16 as a transmission path estimated value PE. Thereafter, the transmission path estimating unit 17 obtains, by complex multiplication, the correlation between the stored signal RF and the corresponding re-encoded signal RE output from the re-encoding unit 25, and performs transmission path estimation. . When the error detection signal ES indicates that there is no error, the transmission path estimating unit 17 converts the transmission path estimation value based on the re-encoded signal RE corresponding to the error detection signal ES into a new transmission path estimation value PE. Is output to the transmission path compensator 16 instead of the transmission path estimation value based on the pilot symbol.
[0058]
On the other hand, when the error detection signal ES indicates that there is an error, the transmission path estimation unit 17 does not output a transmission path estimation value based on the re-encoded signal RE corresponding to the error detection signal ES. In this case, the transmission path estimation unit 17 outputs a transmission path estimation value based on pilot symbols. Note that the transmission channel estimation value based on the immediately preceding re-encoded signal RE may be continuously output.
[0059]
As described above, according to the OFDM communication apparatus of FIG. 1, when an error is present in the re-encoded signal RE, the transmission path compensation is performed without using the error. Can be reduced. For this reason, it is possible to prevent the reception characteristics from greatly deteriorating. Further, error detection can be performed on a symbol basis.
[0060]
When the error detection signal ES output from the symbol error detection unit 26 indicates that an error has been detected, the clock control unit 31 immediately stops supplying a clock to the processing units after the FFT unit 13. When detecting the preamble or the pilot symbol for channel response estimation, the synchronization unit 12 notifies the clock control unit 31 of the detection using the preamble detection signal PA. Then, the clock control unit 31 restarts the supply of the clock to the processing units after the FFT unit 13 of the receiving unit 10. The supply of the clock to at least one of the processing units after the FFT unit 13 may be stopped and restarted.
[0061]
It is also assumed that the clock control unit 31 has been notified of the type of information being received from the transmitting-side OFDM communication device by a control signal or the like indicating a transmission parameter. The clock control unit 31 determines whether to stop the clock supplied to the processing unit after the FFT unit 13 of the reception unit 10 when the symbol error detection unit 26 detects an error, according to the type of information currently received. Determined accordingly.
[0062]
For example, in the case of image data, even if the data of one frame is erroneous due to a bit error, it is hardly detected by human eyes, so that the allowable range of the bit error rate is large. On the other hand, in the case of audio data, if a bit error occurs, it sounds very unpleasant to human ears, so the allowable range of the bit error rate is small. In other words, if the transmitted / received information has a large allowable range of the bit error rate like image data, it is not necessary to stop the receiving operation or request retransmission even if an error is detected. If the transmitted / received information has a small allowable range of the bit error rate like voice data, if an error is detected, it is necessary to stop the receiving operation and request retransmission immediately.
[0063]
Therefore, when the received information is image data, the clock control unit 31 does not stop the clock even if an error is detected, and when the received information is audio data, When detected, stop the clock.
[0064]
Then, fine clock control can be performed in symbol units. Therefore, it is possible to reduce the power consumption of the processing unit after the FFT unit 13 that consumes a large amount of power, and it is possible to greatly reduce the power consumption of the entire receiving unit 10. Further, since error detection is performed in units of symbols, retransmission processing can be performed immediately upon detection of a bit error.
[0065]
(Second embodiment)
FIG. 3 is a block diagram of an OFDM communication device according to the second embodiment of the present invention. The OFDM communication device in FIG. 3 includes a receiving unit 110 and a transmitting unit 140. The receiving unit 110 includes a transmission line distortion amount detecting unit 34 in place of the clock control unit 31 in the receiving unit 10 of FIG. The transmitting section 140 includes a quality determining information adding section 141 instead of the quality determining information adding section 41 in the transmitting section 40 of FIG. In the following figures, illustration of clock supply is omitted. Here, it is assumed that the modulation method of the subcarrier is 16QAM, but the same applies to a case where modulation is performed by another modulation method.
[0066]
FIG. 4 is a signal point constellation diagram showing a signal point constellation of the 16QAM system and an error vector. In FIG. 4, the symbol ● indicates the coordinates of an ideal signal point, and the symbol ○ indicates the actual signal in the output signal RC of the residual phase error estimation / compensation unit 21 after the transmission path compensation and the residual phase error compensation have been performed. 3 shows an example of the coordinates of the signal point.
[0067]
The transmission line distortion amount detection unit 34 calculates the distance between the signal point に よ る of the I and Q received data constituting the signal RC after the residual phase error compensation and the closest ideal signal point 、, The signal is output to the quality determination information adding unit 141 as the distortion amount detection signal PD. The quality judgment information adding unit 141 determines that the larger the transmission path distortion amount detection signal PD is, the larger the transmission path distortion amount is, and determines that the state of the transmission path is poor. The smaller the transmission path distortion amount detection signal PD is, the smaller the transmission path distortion amount is. It can be determined that the transmission path is small and the state of the transmission path is good.
[0068]
The quality judgment information adding section 141 adds the quality judgment information to the information OFDM symbol when the transmission path distortion amount detection signal PD is larger than the threshold value set in the internal register. Is not added to the information OFDM symbol.
[0069]
That is, when the state of the transmission path is good, the probability of occurrence of a bit error is low, so that it is not necessary to add the quality judgment information to the transmission data. Therefore, the quality judgment information signal adding section 141 transmits the transmission data SD instead of the quality judgment information to improve the transmission efficiency. If the state of the transmission path is poor, there is a high probability that a bit error will occur, so it is necessary to add quality determination information to transmission data. Therefore, the quality judgment information signal adding section 141 adds the quality judgment information, for example, for each symbol. Then, error detection can be performed for each symbol, and retransmission processing can be performed immediately.
[0070]
The quality judgment information signal adding section 141 notifies the receiving-side OFDM communication apparatus of whether or not the quality judgment information has been added and the type of signal used as the quality judgment information by a control signal or the like indicating a transmission parameter. I do.
[0071]
As described above, according to the second embodiment, which of the bit error detection and the transmission efficiency is prioritized can be determined according to the state of the transmission path.
[0072]
(Third embodiment)
FIG. 5 is a block diagram of an OFDM communication device according to the third embodiment of the present invention. The OFDM communication device in FIG. 5 includes a receiving unit 210 and a transmitting unit 240. The receiving section 210 is different from the receiving section 10 of FIG. 1 in that a reception power detecting section 36 is provided instead of the clock control section 31. The transmitting section 240 is different from the transmitting section 40 of FIG. 1 in that a quality determining information adding section 241 is provided instead of the quality determining information adding section 41.
[0073]
The reception power detection unit 36 calculates power based on, for example, √ (I * I + Q * Q) based on the I and Q data constituting the reception signal RR output from the radio reception unit 11 and calculates the obtained result as the reception power. The signal is output to the quality judgment information adding unit 241 as a detection signal PW. Then, it can be determined that the greater the value of the received power detection signal PW, the greater the distance between the communication devices, and the smaller the value, the smaller the distance between the communication devices. If a value corresponding to the power can be obtained, a result calculated by another equation may be used as the received power detection signal PW.
[0074]
The quality judgment information signal adding section 241 adds the quality judgment information to the information OFDM symbol when the received power detection signal PW is smaller than the threshold value set in the internal register, and does not add it in other cases.
[0075]
That is, when the distance between the communication devices is small, the probability of occurrence of a bit error is low, and it is not necessary to add the quality determination information to the transmission data. Therefore, the quality judgment information signal adding section 241 transmits the transmission data SD instead of the quality judgment information to improve the transmission efficiency. If the distance between the communication devices is large, the probability of occurrence of a bit error is high, so it is necessary to add quality judgment information to the transmission data. Therefore, the quality judgment information signal adding section 241 adds the quality judgment information to each symbol, for example. Then, error detection can be performed for each symbol, and retransmission processing can be performed immediately.
[0076]
The quality determination information signal adding unit 241 notifies the receiving side OFDM communication apparatus of whether or not the quality determination information has been added and the type of signal used as the quality determination information by a control signal or the like indicating a transmission parameter. I do.
[0077]
As described above, according to the third embodiment, which of the bit error detection and the transmission efficiency is prioritized can be determined according to the magnitude of the received power.
[0078]
(Fourth embodiment)
FIG. 6 is a block diagram of an OFDM communication device according to a fourth embodiment of the present invention. The OFDM communication apparatus in FIG. 6 includes a receiving unit 310 and a transmitting unit 340. The receiving unit 310 is obtained by removing the clock control unit 31 from the receiving unit 10 of FIG. The transmitting section 340 is different from the transmitting section 40 of FIG. 1 in that a quality determining information adding section 341 is provided instead of the quality determining information adding section 41.
[0079]
In addition to the transmission data SD, a transmission data type information signal DI indicating the data type of the transmission data SD is input to the quality determination information adding unit 341. The quality judgment information adding section 341 judges whether to add the quality judgment information based on the transmission data type information signal DI.
[0080]
For example, as described in the first embodiment, the permissible range of the bit error rate is large for image data, and the permissible range of the bit error rate is small for audio data. Therefore, the quality determination information adding unit 341 adds the quality determination information to the information OFDM symbol when the transmission data type information signal DI indicates that the transmission data SD is audio data, and otherwise, The quality judgment information is not added to the information OFDM symbol.
[0081]
That is, when the transmission data SD is image data or the like and the allowable range of the bit error rate is wide, it is not necessary to add the quality determination information to the transmission data. Therefore, the quality judgment information signal adding section 341 transmits the transmission data SD instead of the quality judgment information to improve the transmission efficiency. When the transmission data SD is audio data or the like and the allowable range of the bit error rate is narrow, it is necessary to add quality determination information to the transmission data. Therefore, the quality judgment information signal adding section 341 adds the quality judgment information to each symbol, for example. Then, error detection can be performed for each symbol, and retransmission processing can be performed immediately.
[0082]
The quality determination information signal adding unit 341 notifies the receiving-side OFDM communication apparatus of whether or not the quality determination information has been added and the type of signal used as the quality determination information by a control signal or the like indicating a transmission parameter. I do.
[0083]
As described above, according to the fourth embodiment, which of the bit error detection and the transmission efficiency is prioritized can be determined according to the type of transmission data.
[0084]
(Fifth embodiment)
FIG. 7 is a block diagram of an OFDM communication device according to a fifth embodiment of the present invention. The OFDM communication device in FIG. 7 includes a receiving unit 310 and a transmitting unit 440. The receiving unit 310 is the same as that described with reference to FIG. The transmitting section 440 is different from the transmitting section 40 of FIG. 1 in that a quality determining information adding section 441 is provided instead of the quality determining information adding section 41.
[0085]
The quality determination information adding section 441 receives, in addition to the transmission data SD, a modulation scheme information signal MI indicating a subcarrier modulation scheme. The quality determination information adding section 441 determines whether to add quality determination information based on the modulation scheme information signal MI.
[0086]
FIG. 8 is a characteristic diagram showing the relationship between transmission line distortion and error rate for each modulation scheme. As shown in FIG. 8, there is a difference in a range of allowable transmission line distortion depending on a difference in modulation scheme. For example, comparing the modulation schemes of BPSK, QPSK, 16QAM, and 64QAM, the modulation schemes are BPSK, QPSK, 16QAM, and 64QAM in descending order of allowable transmission line distortion.
[0087]
For example, when the modulation scheme information signal MI indicates that the modulation scheme of the subcarrier is 64QAM, the quality determination information adding unit 441 adds the quality determination information to the information OFDM symbol. No decision information is added to the information OFDM symbol.
[0088]
That is, when the modulation scheme is BPSK or the like and the allowable range of the bit error rate is wide, it is not necessary to add the quality determination information to the transmission data. Therefore, the quality judgment information signal adding section 441 transmits the transmission data SD instead of the quality judgment information to improve the transmission efficiency. When the modulation method is 64QAM or the like and the allowable range of the bit error rate is narrow, it is necessary to add quality judgment information to the transmission data. Therefore, the quality judgment information signal adding section 441 adds the quality judgment information to each symbol, for example. Then, error detection can be performed for each symbol, and retransmission processing can be performed immediately.
[0089]
The quality judgment information signal adding section 441 notifies the receiving side OFDM communication apparatus whether or not the quality judgment information has been added and the type of signal used as the quality judgment information by a control signal or the like indicating a transmission parameter. I do.
[0090]
As described above, according to the fifth embodiment, which of the bit error detection and the transmission efficiency is prioritized can be determined according to the modulation scheme.
[0091]
【The invention's effect】
As described above, according to the OFDM communication apparatus according to the present invention, since the estimation of the transmission path response based on the signal containing the error is not used, it is possible to prevent inappropriate deterioration of the reception characteristic by performing inappropriate transmission path compensation. Can be.
[Brief description of the drawings]
FIG. 1 is a block diagram of an OFDM communication device according to a first embodiment of the present invention.
FIG. 2 is an explanatory diagram of addition of quality determination information.
FIG. 3 is a block diagram of an OFDM communication device according to a second embodiment of the present invention.
FIG. 4 is a signal point constellation diagram showing a signal point constellation and an error vector of the 16QAM system.
FIG. 5 is a block diagram of an OFDM communication device according to a third embodiment of the present invention.
FIG. 6 is a block diagram of an OFDM communication device according to a fourth embodiment of the present invention.
FIG. 7 is a block diagram of an OFDM communication device according to a fifth embodiment of the present invention.
FIG. 8 is a characteristic diagram showing a relationship between a transmission line distortion and an error rate for each modulation method.
FIG. 9 is an explanatory diagram showing an example of a position where a pilot symbol is inserted.
FIG. 10 is an explanatory diagram of adaptive estimation of a channel response.
FIG. 11 is a block diagram illustrating a configuration of a conventional OFDM communication device.
[Explanation of symbols]
10,110,210,310 Receiver
11 Wireless receiver
12 Synchronization unit
13 FFT section
15 Channel estimation compensator
16 Transmission path compensator
17 Transmission channel estimation unit
21 Residual position error estimation compensation unit
22 Error Correction Section
25 Re-encoding unit
26 Symbol error detector (error detector)
31 Clock control unit
34 Transmission line distortion amount detection unit
36 Received power detector
40, 140, 240, 340, 440 Transmitter
41, 141, 241, 341, 441 Quality judgment information adding unit
42 Encoding unit
43 IFFT section
44 Wireless transmitter

Claims (10)

An OFDM communication apparatus comprising: a transmission unit that transmits an orthogonal frequency division multiplexing (OFDM) signal that transmits information by a plurality of subcarriers; and a reception unit that processes the received OFDM signal.
The transmitting unit includes:
It is provided with a quality judgment information adding unit for adding the quality judgment information to the information to be transmitted,
The receiving unit,
An FFT unit that performs an FFT (fast Fourier transform) process on the received and converted OFDM signal into a baseband signal, and outputs the result.
A transmission path estimating unit that stores a signal output by the FFT unit and calculates and outputs a transmission path estimation value;
A transmission path compensation unit that compensates for transmission path distortion and outputs the signal output by the FFT unit using the transmission path estimation value;
An error correction unit that performs an error correction process on the signal whose transmission line distortion has been compensated, and outputs
An error detection unit that performs error detection on the error-corrected signal based on the quality determination information, and outputs an error detection signal indicating the presence or absence of an error.
Re-encoding processing is performed on the signal subjected to the error correction processing, and a re-encoding unit that outputs the signal,
The transmission path estimating unit,
The transmission path estimation value is obtained and output based on a pilot symbol included in the signal output by the FFT unit, and the stored signal is re-encoded by the re-encoding unit corresponding to the stored signal. A transmission path estimation is performed based on the obtained signal, and when the error detection signal indicates that there is no error, a transmission path estimation value based on the re-encoded signal corresponding to the error detection signal is used as the pilot symbol. Output in place of a transmission path estimation value based on the error detection signal, and when the error detection signal indicates that there is an error, the transmission path estimation value based on the re-encoded signal corresponding thereto is not output. Communication device. The OFDM communication device according to claim 1,
The quality determination information adding unit,
An OFDM communication apparatus, wherein the quality judgment information is added for each information OFDM symbol. The OFDM communication device according to claim 2,
An OFDM communication apparatus, wherein the quality determination information is a bit indicating a parity of an information bit in the same symbol. The OFDM communication device according to claim 1,
An OFDM communication apparatus, wherein the quality determination information is a predetermined pattern of a plurality of bits. The OFDM communication device according to claim 1,
A clock is supplied to at least one of the FFT unit, the transmission line estimation unit, the transmission line compensation unit, the error correction unit and the error detection unit, and the error detection signal indicates that there is an error, An OFDM communication apparatus, further comprising a clock control unit that stops supplying a clock and restarts the supply of the clock when the receiving unit receives a predetermined signal. The OFDM communication device according to claim 5,
The clock control unit includes:
An OFDM communication apparatus for determining whether or not to stop supplying the clock according to the type of information being received. The OFDM communication device according to claim 1,
The transmission line distortion is further provided with a transmission line distortion amount detection unit that calculates and outputs a transmission line distortion amount based on a signal point arrangement of the compensated information signal,
The quality determination information adding unit,
An OFDM communication apparatus, which determines whether or not to add the quality determination information according to the transmission path distortion amount. The OFDM communication device according to claim 1,
A power detection unit that obtains and outputs power of the OFDM signal converted to the baseband signal,
The quality determination information adding unit,
An OFDM communication apparatus for determining whether or not to add the quality determination information according to the power. The OFDM communication device according to claim 1,
The quality determination information adding unit,
An OFDM communication apparatus for determining whether or not to add the quality determination information according to a signal indicating the type of information to be transmitted. The OFDM communication device according to claim 1,
The quality determination information adding unit,
An OFDM communication apparatus for determining whether or not to add the quality determination information according to a signal indicating a modulation scheme of the subcarrier.

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