JP3565537B2 - Orthogonal frequency division multiplex modulation signal transmission system - Google Patents

Orthogonal frequency division multiplex modulation signal transmission system Download PDF

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Publication number
JP3565537B2
JP3565537B2 JP16148597A JP16148597A JP3565537B2 JP 3565537 B2 JP3565537 B2 JP 3565537B2 JP 16148597 A JP16148597 A JP 16148597A JP 16148597 A JP16148597 A JP 16148597A JP 3565537 B2 JP3565537 B2 JP 3565537B2
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carrier
code
circuit
signal
transmission
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JPH118604A (en
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俊之 秋山
敦 宮下
誠一 佐野
信夫 塚本
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Hitachi Kokusai Electric Inc
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Hitachi Kokusai Electric Inc
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Description

【0001】
【発明の属する技術分野】
本発明は、直交周波数分割多重変調( Orthogonal Frequency Division Multi−plexing:OFDM)方式の伝送装置において、伝送した情報符号の符号誤り率を低減する伝送符号構成と、この符号構成を用いた伝送方式に関する。
【0002】
【従来の技術】
現在、移動体や地上系のディジタル無線通信用の多重伝送方式として、マルチパス・フェージングや、ゴーストに強いという特徴を有する直交周波数分割多重伝送方式(以下、OFDM方式と記す)が注目されている。
このOFDM方式は、図3に示すように、互いに所定の周波数間隔fs をもって配置された数十本ないしは数百本からなる多数の搬送波を、それぞれシンボル周波数fs’(=1/Ts’)でディジタル変調した信号、すなわち、OFDM信号(直交周波数分割多重変調信号)を用いて情報符号を伝送する方式である。
ここで、時間間隔Ts’は、ディジタル信号のシンボル周期のことである。
そして、このOFDM方式における各搬送波のディジタル変調方式としては、QPSK方式(4相位相偏移変調方式)や、16QAM方式(16値直交振幅変調方式)などが検討されている。
【0003】
各搬送波をQPSK方式でディジタル変調する場合の従来技術によるOFDM伝送装置のブロック回路構成を図4に示す。 ここで、図4の上側が送信装置、下側が受信装置側を表す。
送信装置では、伝送する情報符号をQPSK変調回路1でQPSK方式の複素ベクトル信号(以下、QPSK信号と記す)に変調する。
変調して得たQPSK信号は、分配回路2で各搬送波に分配された後、IFFT回路3で逆離散フーリエ変換(IFFT)される。
この変換処理によりQPSK信号は、シンボル周期Ts’で、互いに周波数間隔fs 離れ、かつ互いに直交するNs 本の搬送波から成る直交周波数分割多重変調方式で多重化された、ベースバンドのOFDM信号に変換される。
そして、該OFDM信号は、ミキサ4に供給され、高周波の送信側局部発振器5で発生した周波数fr の送信側局発信号により、例えば数百MHz帯、或いは数GHz帯の高周波数信号に周波数変換され、電力増幅されて送信アンテナ6から送信される。
【0004】
一方、受信装置では、受信アンテナ7により受信した受信信号を増幅した後、ミキサ8に入力する。 そして、当該受信信号は受信側局部発振器9で発生した周波数fr の受信側局発信号により周波数変換され、多重化されたベースバンドのOFDM信号が再生される。
このOFDM信号は、更にFFT回路10で離散フーリエ変換(FFT)され、各搬送波のベースバンドの複素ベクトル信号Z(n)に分離される。ここで、nは分離された搬送波の番号を表す。
こうして分離された各搬送波の複素ベクトル信号Z(n)は、結合回路11にて送信側での分配回路2と逆の手順により、元の時間順序に並べ替えられ、時間的に連続したQPSK信号に戻され、QPSK復調回路12で復調され、情報符号として出力される。
【0005】
【発明が解決しようとする課題】
ところで、ベースバンドのOFDM信号には、搬送波周波数が、1シンボルの期間、伝送する情報符号に応じた所定の直流レベルになる搬送波( 以下、番号0の搬送波と記す )がある。
一方、受信装置のFFT回路10では、前述のように、入力された信号をそのまま離散フーリエ変換する。 そのため、FFT回路10に入力する直流レベルの調整がずれていると、そのずれた直流レベルも信号成分として変換され、上記番号0の搬送波成分として混入する。
その結果、この番号0の搬送波に対するQPSK方式や16QAM方式の復調をする際に大きな雑音成分となって現れ、復調した符号全体の符号誤り率を増大させることになる。
この問題は、FFT回路10に入力する信号の直流レベルを正確に0レベルに調整すれば回避できる。 しかし、実際の回路ではこの調整が困難な上、温度による回路の動作点の変化を押さえるための特別な回路が必要になり、回路規模の増加と伝送装置の高価格化を招く欠点がある。
本発明の目的は、回路規模を増加させることなく、OFDM信号の復調処理における符号誤り率を低減する伝送符号構成およびこの伝送符号構成を用いた伝送装置を提供することにある。
【0006】
【課題を解決するための手段】
本発明は、上記目的を達成するため、互いに周波数間隔fsあるいはその整数倍離れたNs本の搬送波を、時間間隔T s'( =1/fs ) をシンボル周期としてディジタル変調して情報符号を伝送する直交周波数分割多重変調信号伝送方法において、ベースバンドで互いに直交する上記Ns本の搬送波の内、搬送波周波数が1シンボル期間、伝送する上記情報符号に応じた所定の直流レベルになる搬送波を、受信装置で各シンボルの同期を再生するのに用いるシンボル同期信号あるいは搬送波周波数を再生するのに用いる搬送波再生用同期信号を伝送する搬送波として用いるようにした直交周波数分割多重変調信号の伝送方法である。
【0007】
上記のように、本発明では、復調に際し、直流レベルの影響を受ける番号0の搬送波を、シンボル同期信号あるいは搬送波周波数を再生するのに用いる搬送波再生用同期信号を伝送する搬送波として用いている
【0008】
そのため、復調に際し、直流レベルのずれにより符号誤りを頻繁に起こす搬送波の符号が、伝送符号全体に対する符号誤り率の増加を起こすことがなくなり、伝送された符号の符号誤り率を低減することができる。
【0009】
【発明の実施の形態】
以下、本発明の伝送装置の第1の実施例を図1に示し、詳しく説明する。
なお、ここでは、各搬送波に対するディジタル変調方式として、図4の従来技術と同じ、QPSK方式を用いる場合の回路構成を示している。
上述した様に、本発明の方法ではほとんど従来の回路をそのまま用いることができる。図1の回路は、QPSK変調回路で変調されたQPSK信号を各搬送波に分配する分配回路2を、番号0の搬送波を除いて分配する分配回路2’に変えた点、また受信装置のFFT回路10で離散フーリエ変換して得た各搬送波の信号を再び結合してQPSK信号に戻す結合回路11を、番号0の搬送波の信号を除いて結合する結合回路11’に変えた点だけが、図4の従来の回路と異なる。伝送装置の動作は、番号0の搬送波で情報符号を伝送しない点を除き、従来の回路と同様に実行するので、説明を省略する。
【0010】
OFDM方式で多重化される搬送波の本数Ns は、通常、数百本から数千本に設定する。
例えば、搬送波の本数を1000本に設定した場合、番号0の搬送波の符号の内の10%が符号誤りを起こすとすると、他の搬送波の符号が誤りを起こさなくても、伝送符号全体としての符号誤り率は、1/10になる。
そのため、受信状態が良好でほとんど雑音が無い状態でも、誤り訂正符号能力が高く、符号長が長い誤り訂正符号を用いる必要が生じ、かえって伝送レートを下げる結果になる。
【0011】
これに対し本実施例では、符号誤り率の高い番号0の搬送波を用いないため、伝送された符号全体の符号誤り率は、受信状態で決まる本来の符号誤り率の伝送符号を得ることができる。
なお、本実施例の符号構成では、1000本の搬送波の内の番号0の搬送波が情報符号伝送に使用できなくなるため、伝送装置の伝送レートがやや低下する。しかし、その低減量は、わずか1/1000にしか過ぎない。しかも、回路規模は従来とほとんど変わらず、従って伝送装置の価格の増大も無い。
このように、本実施例による伝送装置では、直流レベルのずれの影響を受ける番号0の搬送波を、情報符号の伝送に使用していないため、直流レベルのずれによって符号誤りを頻繁に起こす搬送波の符号が、伝送符号全体に対する符号誤り率の増加を起こすことがなくなる。
従って、伝送された符号の符号誤り率を低減することができ、また、この効果を得るために回路規模が増大することもなく、伝送装置を低価格に押さえることができる。
【0012】
次に、本発明の第2の実施例を図2に示し、図1と異なる部分の動作について説明する。
本実施例では、送信装置にQPSK変調回路1とは別に、雑音に強いBPSK方式の変調を実行するBPSK変調回路13を設ける。そして、番号0の搬送波を変調する際は、BPSK変調回路13で対応する情報符号を変調し、分配回路2”によって番号0の搬送波に割り当てる。
【0013】
一方、受信装置には、QPSK復調回路12とは別に、BPSK復調回路14を設ける。さらに、FFT回路10で離散フーリエ変換して得た各搬送波の信号の内、番号0の搬送波の信号を除く搬送波の信号を、送信側での分配回路2”と逆の手順により、元の時間順序に並べ替え、時間的に連続したQPSK信号に戻し、番号0の搬送波の信号を、BPSK信号に戻す結合回路11”を設ける。
そして、これらFFT回路10、結合回路11”により、QPSK信号、BPSK信号に戻された信号は、それぞれQPSK復調回路12、BPSK復調回路14で情報符号に復調されて出力される。
本実施例は、直流レベルのずれの影響を受けて符号誤りを起こし易い番号0の搬送波を、雑音に強いBPSK方式で変調しているため、番号0の搬送波の符号の符号誤り率が低下し、伝送された符号全体の符号誤り率を低減することができる。なお、本実施例では新たな回路が必要になるため回路規模がやや増大する。しかし、番号0の搬送波でも情報符号を伝送しているため、伝送レートの減少量を減らすことができる。
【0014】
また、上記の第1の実施例では、番号0の搬送波を全く使用しないものとして説明した。 しかし、OFDM方式の伝送装置では、通常、受信信号を復調するのに必要な伝送信号のシンボル位相と搬送波周波数を再生するための同期符号を伝送信号の所定シンボル毎に挿入している。
そこで、この同期符号を、情報符号を伝送しない番号0の搬送波を用いて伝送するようにしても良い。この様にすると、もともと同期符号の伝送に用いていたシンボルで情報符号を伝送できるようになるため、伝送レートの低減量を減らすことができる。
【0015】
【発明の効果】
以上説明した如く、本発明による伝送符号構成では、直流レベルのずれの影響を受ける番号0の搬送波を、雑音に強いBPSK方式で変調して情報符号を伝送するか、あるいは、この番号0の搬送波では情報符号を伝送しない符号構成としているため、直流レベルのずれによって符号誤りを頻繁に起こす搬送波の符号が、伝送符号全体に対する符号誤り率の増加を起こすことがなくなる。 従って、回路規模を増大させることなく、伝送された符号の符号誤り率を低減することができる。
【図面の簡単な説明】
【図1】本発明のOFDM方式の伝送装置の第1の実施例の構成を示すブロック図。
【図2】本発明のOFDM方式の伝送装置の第2の実施例の構成を示すブロック図。
【図3】一般的なOFDM方式の搬送波の周波数配置を示す図。
【図4】従来のOFDM方式の伝送装置の構成を示すブロック図。
【符号の説明】
1:QPSK変調回路、2,2’,2”:分配回路、3:IFFT回路、4,8:ミキサ、5:送信側局部発振器、6:送信アンテナ、7:受信アンテナ、9:受信側局部発振器、10:FFT回路、11,11’,11”結合回路、12:QPSK復調回路、13:BPSK変調回路、14:BPSK復調回路。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmission code configuration for reducing a code error rate of a transmitted information code in a transmission apparatus of an Orthogonal Frequency Division Multiplexing (OFDM) system, and a transmission system using the code configuration. .
[0002]
[Prior art]
At present, an orthogonal frequency division multiplexing transmission system (hereinafter, referred to as an OFDM system), which has characteristics of being resistant to multipath fading and ghosts, is attracting attention as a multiplex transmission system for digital radio communication of a mobile or terrestrial system. .
In this OFDM system, as shown in FIG. 3, a large number of tens or hundreds of carrier waves arranged at a predetermined frequency interval fs are digitally converted at a symbol frequency fs '(= 1 / Ts'). In this method, an information code is transmitted using a modulated signal, that is, an OFDM signal (orthogonal frequency division multiplex modulation signal).
Here, the time interval Ts' is a symbol period of the digital signal.
As a digital modulation method for each carrier in the OFDM method, a QPSK method (four-phase shift keying method), a 16QAM method (16-level quadrature amplitude modulation method), and the like are being studied.
[0003]
FIG. 4 shows a block circuit configuration of an OFDM transmission apparatus according to the prior art when each carrier is digitally modulated by the QPSK method. Here, the upper side of FIG. 4 represents the transmitting apparatus, and the lower side of FIG.
In the transmitting device, the information code to be transmitted is modulated by the QPSK modulation circuit 1 into a complex vector signal of the QPSK system (hereinafter, referred to as a QPSK signal).
The QPSK signal obtained by the modulation is distributed to each carrier by the distribution circuit 2, and then subjected to inverse discrete Fourier transform (IFFT) by the IFFT circuit 3.
By this conversion processing, the QPSK signal is converted into a baseband OFDM signal multiplexed by the orthogonal frequency division multiplexing modulation method including Ns carrier waves that are mutually separated by the frequency interval fs and are orthogonal to each other at the symbol period Ts ′. You.
Then, the OFDM signal is supplied to a mixer 4 and frequency-converted into a high-frequency signal of, for example, several hundred MHz band or several GHz band by a transmitting-side local signal of a frequency fr generated by a high-frequency transmitting-side local oscillator 5. The power is amplified and transmitted from the transmitting antenna 6.
[0004]
On the other hand, in the receiving device, the received signal received by the receiving antenna 7 is amplified and then input to the mixer 8. Then, the received signal is frequency-converted by the receiving-side local signal having the frequency fr generated by the receiving-side local oscillator 9, and the multiplexed baseband OFDM signal is reproduced.
This OFDM signal is further subjected to a discrete Fourier transform (FFT) by the FFT circuit 10 to be separated into a baseband complex vector signal Z (n) of each carrier. Here, n represents the number of the separated carrier.
The complex vector signal Z (n) of each carrier separated in this manner is rearranged in the original time order in the coupling circuit 11 by the reverse procedure of the distribution circuit 2 on the transmission side, and the temporally continuous QPSK signal , Demodulated by the QPSK demodulation circuit 12, and output as an information code.
[0005]
[Problems to be solved by the invention]
By the way, in the baseband OFDM signal, there is a carrier (hereinafter, referred to as a number 0 carrier) whose carrier frequency becomes a predetermined DC level according to the information code to be transmitted during one symbol period.
On the other hand, in the FFT circuit 10 of the receiving device, as described above, the input signal is directly subjected to discrete Fourier transform. Therefore, if the adjustment of the DC level input to the FFT circuit 10 is deviated, the deviated DC level is also converted as a signal component, and is mixed as the carrier component of the number 0.
As a result, a large noise component appears when demodulating the QPSK system or 16QAM system with respect to the carrier having the number 0, thereby increasing the code error rate of the entire demodulated code.
This problem can be avoided by adjusting the DC level of the signal input to the FFT circuit 10 to exactly 0 level. However, in an actual circuit, this adjustment is difficult, and a special circuit for suppressing a change in the operating point of the circuit due to temperature is required, which has a drawback of increasing the circuit scale and increasing the price of the transmission device.
An object of the present invention is to provide a transmission code configuration for reducing a code error rate in an OFDM signal demodulation process without increasing a circuit scale, and a transmission device using the transmission code configuration.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention transmits an information code by digitally modulating Ns carrier waves having a frequency interval fs or an integer multiple thereof from each other with a time interval Ts ' ( = 1 / fs ) as a symbol period. In the orthogonal frequency division multiplexing modulation signal transmission method, among the Ns carrier waves orthogonal to each other in the baseband, a carrier wave whose carrier frequency becomes a predetermined DC level corresponding to the information code to be transmitted for one symbol period is received. This is a method of transmitting an orthogonal frequency division multiplex modulation signal used as a carrier for transmitting a symbol synchronization signal used for reproducing synchronization of each symbol or a carrier reproduction synchronization signal used for reproducing a carrier frequency in a device.
[0007]
As described above, in the present invention, at the time of demodulation, the carrier wave of number 0, which is affected by the DC level, is used as a carrier wave for transmitting a symbol synchronization signal or a carrier reproduction synchronization signal used for reproducing a carrier frequency .
[0008]
Therefore, in demodulation, a code of a carrier that frequently causes a code error due to a shift in a DC level does not cause an increase in a code error rate for the entire transmission code, and can reduce a code error rate of a transmitted code. .
[0009]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a first embodiment of the transmission apparatus of the present invention is shown in FIG. 1 and will be described in detail.
Here, the circuit configuration in the case where the QPSK system is used as the digital modulation system for each carrier as in the prior art of FIG. 4 is shown.
As described above, almost all conventional circuits can be used as they are in the method of the present invention. The circuit of FIG. 1 is different from the FFT circuit of the receiving apparatus in that the distribution circuit 2 for distributing the QPSK signal modulated by the QPSK modulation circuit to each carrier is changed to a distribution circuit 2 'for distributing the carrier except for the carrier of number 0. The only difference is that the coupling circuit 11 that combines the signals of the respective carrier waves obtained by performing the discrete Fourier transform in step 10 and combines them back into a QPSK signal is replaced by a coupling circuit 11 ′ that combines the signals except for the carrier wave number 0. 4 is different from the conventional circuit of FIG. The operation of the transmission device is performed in the same manner as the conventional circuit except that the information code is not transmitted on the carrier wave of number 0, and thus the description is omitted.
[0010]
The number Ns of carriers multiplexed by the OFDM method is usually set to several hundred to several thousand.
For example, if the number of carriers is set to 1000, and if 10% of the codes of the carrier of number 0 cause a code error, even if the codes of other carriers do not cause errors, the transmission code as a whole will not The bit error rate becomes 1/10 4 .
Therefore, even when the reception state is good and there is almost no noise, it is necessary to use an error correction code having a high error correction code capability and a long code length, which results in a reduction in the transmission rate.
[0011]
On the other hand, in the present embodiment, since the carrier with the number 0 having a high code error rate is not used, the code error rate of the entire transmitted code can be obtained as the transmission code of the original code error rate determined by the reception state. .
In the code configuration of the present embodiment, the carrier of number 0 out of the 1000 carriers cannot be used for information code transmission, so that the transmission rate of the transmission device is slightly reduced. However, the reduction is only 1/1000. In addition, the circuit scale is almost the same as that of the related art, so that the price of the transmission device does not increase.
As described above, in the transmission apparatus according to the present embodiment, since the carrier of number 0 affected by the DC level shift is not used for transmitting the information code, the carrier of the carrier that frequently causes a code error due to the DC level shift is not used. The code does not cause an increase in the code error rate for the entire transmission code.
Therefore, the code error rate of the transmitted code can be reduced, and the transmission device can be kept inexpensive without increasing the circuit scale to obtain this effect.
[0012]
Next, a second embodiment of the present invention is shown in FIG. 2, and an operation of a portion different from FIG. 1 will be described.
In this embodiment, in addition to the QPSK modulation circuit 1, a BPSK modulation circuit 13 that performs noise-resistant BPSK modulation is provided in the transmission apparatus. Then, when modulating the carrier wave of number 0, the corresponding information code is modulated by the BPSK modulation circuit 13 and assigned to the carrier wave of number 0 by the distribution circuit 2 ″.
[0013]
On the other hand, the receiving apparatus is provided with a BPSK demodulation circuit 14 separately from the QPSK demodulation circuit 12. Further, of the carrier signals obtained by the discrete Fourier transform by the FFT circuit 10, the carrier signals excluding the carrier signal of number 0 are converted to the original time by the reverse procedure of the distribution circuit 2 ″ on the transmission side. There is provided a coupling circuit 11 "which rearranges in order, restores a temporally continuous QPSK signal, and restores the carrier signal of number 0 to a BPSK signal.
The signals returned to the QPSK signal and the BPSK signal by the FFT circuit 10 and the coupling circuit 11 ″ are demodulated into information codes by the QPSK demodulation circuit 12 and the BPSK demodulation circuit 14, respectively, and are output.
In the present embodiment, the carrier wave of number 0, which is susceptible to a code error due to the influence of the DC level shift, is modulated by the BPSK method that is strong against noise, so that the code error rate of the code of the carrier wave of number 0 decreases. In addition, the code error rate of the entire transmitted code can be reduced. In this embodiment, since a new circuit is required, the circuit scale is slightly increased. However, since the information code is transmitted even with the carrier having the number 0, the amount of reduction in the transmission rate can be reduced.
[0014]
In the first embodiment, the description has been made on the assumption that the carrier wave of number 0 is not used at all. However, in a transmission apparatus of the OFDM system, a synchronization code for reproducing a symbol phase and a carrier frequency of a transmission signal necessary for demodulating a received signal is inserted for each predetermined symbol of the transmission signal.
Therefore, the synchronization code may be transmitted using a carrier wave of number 0 which does not transmit the information code. By doing so, the information code can be transmitted using the symbols originally used for the transmission of the synchronization code, so that the amount of reduction in the transmission rate can be reduced.
[0015]
【The invention's effect】
As described above, in the transmission code configuration according to the present invention, the information code is transmitted by modulating the carrier of number 0 affected by the DC level shift by the noise-resistant BPSK method, or Since the code configuration does not transmit the information code, the carrier code that frequently causes a code error due to a shift in the DC level does not cause an increase in the code error rate for the entire transmission code. Therefore, the code error rate of the transmitted code can be reduced without increasing the circuit scale.
[Brief description of the drawings]
FIG. 1 is a block diagram showing the configuration of a first embodiment of an OFDM transmission apparatus according to the present invention.
FIG. 2 is a block diagram showing a configuration of a second embodiment of an OFDM transmission apparatus according to the present invention.
FIG. 3 is a diagram showing a frequency arrangement of carriers in a general OFDM system.
FIG. 4 is a block diagram showing a configuration of a conventional OFDM transmission apparatus.
[Explanation of symbols]
1: QPSK modulation circuit, 2, 2 ′, 2 ″: distribution circuit, 3: IFFT circuit, 4, 8: mixer, 5: transmitting-side local oscillator, 6: transmitting antenna, 7: receiving antenna, 9: receiving-side local Oscillator, 10: FFT circuit, 11, 11 ', 11 "coupling circuit, 12: QPSK demodulation circuit, 13: BPSK modulation circuit, 14: BPSK demodulation circuit.

Claims (1)

互いに周波数間隔fsあるいはその整数倍離れたNs本の搬送波を、時間間隔TNs carrier waves separated from each other by a frequency interval fs or an integer multiple thereof are separated by a time interval T s'(s' ( =1/fs= 1 / fs )) をシンボル周期としてディジタル変調して情報符号を伝送する直交周波数分割多重変調信号伝送方法において、ベースバンドで互いに直交する上記Ns本の搬送波の内、搬送波周波数が1シンボル期間、伝送する上記情報符号に応じた所定の直流レベルになる搬送波を、受信装置で各シンボルの同期を再生するのに用いるシンボル同期信号あるいは搬送波周波数を再生するのに用いる搬送波再生用同期信号を伝送する搬送波として用いることを特徴とする直交周波数分割多重変調信号の伝送方法。In the orthogonal frequency division multiplexing signal transmission method of transmitting an information code by digitally modulating a symbol period as a symbol period, among the Ns carrier waves orthogonal to each other in the baseband, the carrier frequency is transmitted to the information code for one symbol period. A carrier wave having a predetermined DC level corresponding to the carrier wave is used as a carrier for transmitting a symbol synchronization signal used for reproducing synchronization of each symbol in a receiving device or a carrier reproduction synchronization signal used for reproducing a carrier frequency. A method for transmitting an orthogonal frequency division multiplex modulation signal.
JP16148597A 1997-06-18 1997-06-18 Orthogonal frequency division multiplex modulation signal transmission system Expired - Fee Related JP3565537B2 (en)

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JP3796076B2 (en) * 1999-09-07 2006-07-12 松下電器産業株式会社 OFDM communication device
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