JP3809561B2 - Frequency error information detector - Google Patents

Description

【００６５】
次に、電力比算出部４５において、２つの電力計算部４４ａ、４４ｂから入力される２つの電力値の比（正負複素相関比）を算出し、当該算出結果を周波数誤差検出部４６へ出力する。
次に、周波数誤差検出部４６において、電力比算出部４５から入力される正負複素相関比に基づいて周波数誤差を検出し、当該検出結果から周波数誤差情報を生成して周波数誤差変換部４７へ出力する。
【００６６】
次に、周波数誤差変換部４７において、入力された周波数誤差情報に基づいて直交検波部４１における直交検波で用いられるローカル周波数に関する制御を行うための制御情報を生成し、生成した制御情報を平均化処理部４８へ出力する。
次に、平均化処理部４８において、入力される制御情報を平均化処理し、これにより例えば突発的に起きると予測される演算結果の大幅なずれを吸収して低減させ、当該平均化後の制御情報を直交検波部４１に対して与える。
【００６７】
なお、制御情報としては、例えば直交検波部４１で用いられるローカル周波数についての周波数誤差を補正するためのオフセット周波数（例えば、周波数のずれの大きさ及び正負の方向）の情報などを用いることができる。
【００６８】
ここで、制御情報を平均化するための演算式の一例を式２に示す。なお、制御情報の平均化は連続したＭ（Ｍは複数）個の制御情報について行われるとしてあり、Ｘａｖｅは前回までの制御情報の平均化結果であるとし、Ｘａｖｅ’は今回の制御情報を含めた平均化結果であるとし、Ｘｔは今回（現在）のフレームにおいて算出された制御情報であるとし、λは０＜λ＜１となる忘却係数であるとする。
【００６９】
【数２】

【００７０】
そして、直交検波部４１では、入力される制御情報が、例えば次の受信フレームの直交検波において、当該直交検波部４１に対応したキャリアの受信信号に対して与える逆位相の回転量を制御するための周波数誤差補正値の情報として使用され、これにより、周波数誤差が補正される。
【００７１】
以上のように、本例の無線通信システムでは、例えば一定長の伝送データ毎に予め定められた一定のパターンを有する信号（ユニークワード）が付加されたフレーム構成を有する伝送信号系列が用いられて、このような伝送信号系列が送信側により変調されることで得られる変調信号が当該送信側から無線送信され、受信側により受信した当該変調信号から前記伝送信号系列を復調するような伝送系において、送信側と受信側とで、次のような処理を行う。
【００７２】
すなわち、送信側では、上記のような伝送信号系列がＮ（Ｎ≧２）個存在する場合に、各伝送信号系列をＮ個の異なるローカル周波数で直交変調し、当該直交変調により得られるＮ個の変調信号（変調後のＮ個のキャリア信号）を合成して、当該合成結果を変調後のマルチキャリア信号として無線送信する。
【００７３】
一方、受信側では、送信側から無線送信される前記合成された変調信号を受信して、当該受信信号を前記Ｎ個の異なるローカル周波数と同一の周波数により直交検波してＮ個の受信信号系列を取得し、これら直交検波後のＮ個の受信信号系列の中で最も信頼度が高い最適な受信信号系列を選択するために用いる各受信信号系列毎のパラメータを算出し、これら直交検波後のＮ個の受信信号系列から各受信信号系列毎の周波数誤差情報を算出し、前記算出されたパラメータを比較して前記最適な受信信号系列についての周波数誤差情報を選択し、選択した周波数誤差情報に基づいて例えば前記Ｎ個の受信信号系列が含み持つ周波数誤差を補正する値を算出し、算出した周波数誤差の補正値を前記直交検波を行う機能部に対して入力して当該補正値に基づいて周波数誤差を補正する。
【００７４】
また、本例の無線通信システムでは、好ましい態様例として、直交検波後のＮ個の受信信号系列における各ユニークワード部と当該各ユニークワード部に対応して当該受信側に予め設定されたユニークワードパターンとの複素相関演算を行い、各受信信号系列について得られる複素相関値を各受信信号系列の最適受信系列選択パラメータとして用いる。
【００７５】
また、本例の無線通信システムの受信側では、好ましい態様例として、直交検波後のＮ個の受信信号系列における各ユニークワード部と当該各ユニークワード部に対応して当該受信側に予め設定された正負両方向に故意に周波数オフセットを与えたユニークワードパターンとの複素相関演算を行い、当該演算結果に基づいて各受信信号系列についての周波数誤差情報を算出する。
【００７６】
また、本例の無線通信システムでは、好ましい態様例として、例えば自動周波数制御を行ってデジタル情報信号を伝送することが可能な構成において、送信側の無線機と受信側の無線機との間で発生するキャリア周波数のずれによる受信側における受信信号の位相回転の成分を補正する。なお、周波数ずれの補正は、例えば受信信号の位相を逆回転させる仕方や、或いは、例えばローカル周波数を調整する仕方などにより行うことができる。
【００７７】
このように、本例の無線通信システムでは、Ｎ個の受信信号系列についての周波数誤差情報の中から最適なものを選択して、選択した周波数誤差情報に基づいてＮ個の直交検波部のローカル周波数に関する周波数ずれを補正する制御を行う方法により、送受信無線機間におけるキャリア周波数のずれによる周波数誤差をＮ個の伝送信号系列に基づいて検出して、これにより、例えば従来と比べてより正確な周波数誤差の補正値により各伝送信号系列についての周波数誤差を補正することが可能となり、通信品質の向上を図ることができる。
【００７８】
ここで、本例では、周波数誤差算出部３３ａ、３３ｂの機能により周波数誤差情報検出手段が構成されており、最適受信系列選択パラメータ算出部３２ａ、３２ｂの機能によりパラメータ情報取得手段が構成されており、最適受信系列選択部３４の機能及び周波数誤差制御部３５の機能により周波数誤差情報選択手段が構成されており、これらの機能手段により周波数誤差情報検出装置の機能が構成されている。
【００７９】
また、本例では、ユニークワードについての複素相関値である最適受信系列選択パラメータが、検出される周波数誤差情報の信頼度を反映するパラメータ情報として用いられている。
また、本例では、ユニークワードのデータが、所定パターンのデータとして用いられている。
また、本例では、各キャリア毎に対応した直交検波部３１ａ、３１ｂにおいて直交検波のために用いられるローカル周波数の信号が、各キャリア毎の検波用周波数信号として用いられている。
【００８０】
また、本例では、送信側装置と受信側装置との間で発生するキャリア周波数のずれによる受信側装置における受信信号の位相回転の成分を補正することや、或いは、各キャリア毎に対応した直交検波部３１ａ、３１ｂにおいて直交検波のために用いられるローカル周波数を補正することにより、各キャリア毎の検波用周波数信号についての周波数誤差を補正することが行われている。
【００８１】
ここで、本発明に係る周波数誤差情報検出装置や無線通信システムや送信側装置や受信側装置などの構成としては、必ずしも以上に示したものに限られず、種々な構成が用いられてもよい。
また、本発明の適用分野としては、必ずしも以上に示したものに限られず、本発明は、種々な分野に適用することが可能なものである。
【００８２】
また、本発明に係る周波数誤差情報検出装置や無線通信システムや送信側装置や受信側装置などにおいて行われる各種の処理としては、例えばプロセッサやメモリ等を備えたハードウエア資源においてプロセッサがＲＯＭ（Read Only Memory）に格納された制御プログラムを実行することにより制御される構成が用いられてもよく、また、例えば当該処理を実行するための各機能手段が独立したハードウエア回路として構成されてもよい。
また、本発明は上記の制御プログラムを格納したフロッピー（登録商標）ディスクやＣＤ（Co mpact Disc）−ＲＯＭ等のコンピュータにより読み取り可能な記録媒体や当該プログラム（自体）として把握することもでき、当該制御プログラムを記録媒体からコンピュータに入力してプロセッサに実行させることにより、本発明に係る処理を遂行させることができる。
【００８３】
【発明の効果】
以上説明したように、本発明に係る周波数誤差情報検出装置などによると、マルチキャリア通信により受信される信号についての周波数誤差に関する情報を検出するに際して、受信信号に含まれるキャリア毎に対応した信号に基づいて当該信号についての周波数誤差に関する情報を検出し、受信信号に含まれるそれぞれのキャリア毎に対応した信号に基づいて検出される周波数誤差情報の信頼度を反映するパラメータ情報を取得し、取得される複数のパラメータ情報に基づいて検出される周波数誤差情報の信頼度が高いとみなされるキャリアに対応した信号についての周波数誤差情報を選択するようにしたため、このような信頼度が高くて精度が高いとみなされる周波数誤差情報を例えばＡＧＣ処理に適用することにより、周波数誤差を精度よく補正することができる。
【図面の簡単な説明】
【図１】 無線通信システムの一例を示す図である。
【図２】 本発明の一実施例に係る自動周波数制御を行う回路の一例を示す図である。
【図３】 自動周波数制御を行うための回路の構成の一例を説明するための図である。
【図４】 従来例に係る自動周波数制御を行う回路の一例を示す図である。
【符号の説明】
１ａ、１ｂ・・ユニークワード付加部、 ２ａ、２ｂ・・変調信号生成部、
３ａ、３ｂ・・直交変調部、 ４・・加算器、 ５・・無線変調部、
６、１３、１５・・局部発振部、 ７、１４、１６・・周波数変換部、
８・・電力増幅部、 ９、１１・・アンテナ、 １２・・高周波増幅部、
１７・・無線復調部、 １８ａ、１８ｂ・・直交検波部、
１９ａ、１９ｂ・・ＡＦＣ処理部、 ２０・・ＡＦＣ制御部、
２１ａ、２１ｂ・・同期処理部、 ２２ａ、２２ｂ・・等化処理部、
２３ａ、２３ｂ・・復調データ生成部、[0001]
BACKGROUND OF THE INVENTION
The present invention, for example, is a frequency error applicable to an automatic frequency control (AFC) system used in a receiving unit of a radio that performs multicarrier transmission in which the number of carriers (carrier waves) is N (N is a plurality). Regarding information detection devices, etc.
In particular, a carrier frequency generated between a transmitting-side radio and a receiving-side radio by selecting optimum frequency error information from frequency error information calculated from N received signal sequences transmitted by N carriers. The present invention relates to a technique capable of improving communication quality by correcting a phase rotation component of a received signal sequence due to a shift.
[0002]
[Prior art]
For example, in a communication device on the receiving side in digital wireless communication, a modulated signal is orthogonally quasi-synchronously detected using a fixed frequency oscillator and demodulated by digital signal processing. However, in such wireless communication, a frequency shift occurs due to a frequency setting error of the local oscillator or a temperature change between the transmitting wireless device and the receiving wireless device. For this reason, in order to obtain a correct demodulated signal at the receiving side device, it is necessary to compensate for signal distortion due to frequency shift.
[0003]
Here, normally, in the case of digital wireless communication, for example, a signal of a known pattern is transmitted between the transmission side and the reception side such as a unique word used for acquisition of synchronization or training of a waveform equalizer. It is added to the transmission data.
2. Description of the Related Art Conventionally, a method is known in which a receiver detects a phase error between a unique word in a received signal and a unique word pattern known in the receiver, thereby compensating for a frequency error. As a method capable of compensating for the frequency error in this way, for example, a correlation peak detection type AFC method is known.
[0004]
FIG. 4 shows a configuration example of a circuit for performing automatic frequency control according to a conventional example. The circuit shown in the figure is applied to the receiving side of the wireless communication system as shown in FIG. 1B used in the description of the embodiment of the present invention described later, specifically, two orthogonal The detectors 51a and 51b correspond to the two orthogonal detectors 18a and 18b shown in FIG. 1B, and the two frequency error calculators 52a and 52b are the two AFC processors 19a shown in FIG. 1B. 19b, the frequency error control unit 53 and the error correction value calculation unit 54 correspond to the function of the AFC control unit 20 shown in FIG.
[0005]
The circuit shown in FIG. 4 shows a configuration example in the case where the number of carriers of a multicarrier communication signal received by the receiving side apparatus is 2 (N = 2). Signals corresponding to the two included carriers are shown as “first carrier communication signal” and “second carrier communication signal”, respectively.
[0006]
In the circuit shown in the figure, the first quadrature detection unit 51a detects the first carrier communication signal from the received multicarrier communication signal, and the first frequency error calculation unit 52a performs frequency error information based on the detection result. Is calculated. Similarly, the second quadrature detection unit 51b detects the second carrier communication signal from the received multicarrier communication signal, and the second frequency error calculation unit 52b calculates frequency error information based on the detection result. . Further, the frequency error control unit 53 calculates an error correction value using the frequency error information calculated from the frequency error information calculated by the first frequency error calculation unit 52a and the frequency error information calculated by the second frequency error calculation unit 52b. The error correction value calculation unit 54 calculates the correction value of the frequency error based on the output value, and is used for the quadrature detection of the first quadrature detection unit 51a based on the frequency error correction value. The frequency shift about the frequency (local frequency) of the signal and the frequency shift about the frequency (local frequency) of the detection signal used in the second quadrature detection unit 51b are corrected.
[0007]
In addition, the frequency error information about the signal corresponding to each carrier corresponds to each carrier by using, for example, a method as shown in FIG. 3 used in the description of the embodiment of the present invention described later. It is possible to calculate based on unique word data in the received signal and unique word data frequency offset in both positive and negative directions prepared on the receiving side.
[0008]
Here, as the frequency error information output from the frequency error control unit 53 to the error correction value calculation unit 54, for example, as shown in the following documents 1 and 2, there are two pieces of input frequency error information. Are selected from one of the predetermined frequency error information or the sum of two input frequency error information.
[0009]
Specifically, the “multicarrier modulation receiver” described in Japanese Patent Laid-Open No. 9-74363 (reference 1) receives a multiplexed signal obtained by modulating and multiplexing each of a plurality of carriers by a plurality of data. When demodulating, the output level of the data transmitted by one or more predetermined frequency carrier waves among the demodulated data is measured and mixed with the received multiplexed signal so that the output level is maximized. The frequency of the local oscillation signal is determined. Further, in the technique described in this document 1, the direction and amount of the frequency shift can be obtained only by once obtaining a predetermined parameter for evaluating the frequency shift regarding both ends (maximum frequency and minimum frequency) of the frequency band of the received multiplexed signal. It is intended to detect both.
[0010]
In addition, in the frequency deviation detector of “Frequency Deviation Detector and Automatic Frequency Control Circuit Using the Frequency Deviation Detector” described in Japanese Patent Laid-Open No. 10-56488 (Document 2), a matched filter that inputs and processes a complex baseband signal The frequency deviation of the complex baseband signal is detected from the output from the filter and the output from the polar filter that inputs and processes the complex baseband signal. In this case, the power of the output from the matched filter is detected. The detected value of the frequency deviation is changed according to the above. Further, in the automatic frequency control circuit described in Document 2, the reception frequency at the time of quadrature detection of the reception signal is controlled based on the detected value of the frequency deviation, and the plurality of reception signals included in the multicarrier signal are controlled. Control of the reception frequency at the time of quadrature detection of the reception signal based on the result of adding the detected value of the frequency deviation is performed.
[0011]
[Problems to be solved by the invention]
However, in the conventional detection of frequency error information as described above, for example, when performing multicarrier transmission, the accuracy of the frequency error information used on the receiving side may be insufficient. There was a problem that deterioration might be caused.
[0012]
Specifically, for example, when a single transmission signal sequence is subjected to quadrature modulation and quadrature detection at a single local frequency by correlation peak type AFC, a unique word added to the single transmission signal sequence is used. The single frequency error information calculated on the receiving side by the offset unique word and the actual frequency error information generated between the transmitting and receiving radios may be different. If the AFC process is performed using the frequency error correction value generated based on the frequency error information, communication quality may be deteriorated.
[0013]
Further, for example, in the technique described in Document 1, it is understood that AFC processing is performed by data transmitted by a carrier having a predetermined frequency among a plurality of data, but this is used for AFC processing. Since preferable data (carrier wave for transmitting data) can be dynamically changed, the accuracy of AFC processing sometimes deteriorates. Compared with the present invention described later, this document 1 does not describe a technique for dynamically selecting preferable data from the plurality of data and a technique for the selection method.
[0014]
In addition, for example, in the technique described in Document 2, it is understood that AFC processing is performed based on the result of adding a plurality of frequency deviations corresponding to a plurality of carriers, but the accuracy of these plurality of frequency deviations varies. For this reason, the accuracy of the AFC process may not be sufficiently obtained. Compared with the present invention described later, this document 2 does not describe a technique for dynamically selecting a preferred frequency deviation from a plurality of frequency deviations corresponding to a plurality of carriers or a technique for selecting the frequency deviation. .
[0015]
The present invention has been made in view of the above-described conventional circumstances, and selects frequency error information that is considered to have high reliability when detecting information related to a frequency error for a signal received by multicarrier communication. An object of the present invention is to provide a frequency error information detecting device capable of performing
Further, the present invention uses such a frequency error information detection apparatus to correct a frequency shift between transmitting and receiving radios when a multicarrier transmission signal sequence is wirelessly transmitted at a local frequency for each carrier. An object of the present invention is to provide a wireless communication system capable of improving communication quality by correcting frequency error information.
[0016]
[Means for Solving the Problems]
In order to achieve the above object, the frequency error information detection apparatus according to the present invention detects frequency error information (frequency error information) for a signal received by multicarrier communication as follows. Select information.
That is, the frequency error information detection means detects information related to the frequency error for the signal based on the signal corresponding to each carrier included in the received signal, and the parameter information acquisition means corresponds to each carrier included in the received signal. The parameter information reflecting the reliability of the frequency error information detected by the frequency error information detecting means is acquired based on the received signal, and a plurality of parameter information (a plurality of parameters information acquired by the parameter information acquiring means is acquired by the frequency error information selecting means) Frequency error information for a signal corresponding to a carrier that is considered to have high reliability of the frequency error information detected by the frequency error information detecting means.
[0017]
Therefore, based on the parameter information that reflects the reliability of the detected frequency error information, the frequency error information that is considered highly reliable from the frequency error information for the signal corresponding to each carrier included in the received signal. Therefore, by applying frequency error information that is considered to be highly reliable and highly accurate, for example, to AGC processing, for example, a frequency shift (error) for each carrier generated in a received signal, Alternatively, the frequency error can be accurately corrected with respect to a local frequency shift (error) used for detection of each carrier on the receiving side.
[0018]
Here, as multicarrier communication, for example, communication by various methods such as an orthogonal frequency division multiplexing (OFDM) method may be used. As a communication signal by multicarrier communication, for example, a signal that divides a signal to be transmitted into a plurality of routes and modulates and transmits the divided signals of each route with different frequencies (different carriers) is used.
In addition, as the number of carriers in multicarrier communication (the number of carriers included in the received signal), various numbers may be used as long as they are plural.
[0019]
In addition, as the frequency error information, various types of information regarding the frequency error may be used. For example, when a communication signal of multicarrier communication is transmitted from the transmission side device to the reception side device, the information is caused by the transmission side device. Information on frequency error, information on frequency error caused by receiving side device, information on frequency error caused by both sending side device and receiving side device, and transmission path between sending side device and receiving side device Information about the resulting frequency error can be used.
[0020]
Various information may be used as parameter information that reflects the reliability of detected frequency error information. For example, any carrier in the frequency error information for a signal corresponding to each carrier is supported. It is only necessary to use information that can determine whether the accuracy of the frequency error information for the received signal is high.
[0021]
Further, the number of frequency error information selected by the frequency error information selecting means may be 1 or 2 or more. Specifically, as an example, the frequency error information selection unit is configured to output a signal corresponding to one carrier that is regarded as having the highest reliability based on a plurality of parameter information about a plurality of signals corresponding to a plurality of carriers. As another example, the frequency error information is selected, and as another example, two or more signals corresponding to two or more carriers regarded as having relatively high reliability based on a plurality of parameter information about a plurality of signals corresponding to a plurality of carriers Select two or more frequency error information for.
[0022]
Further, the processing order of the detection of the frequency error information by the frequency error information detection means and the selection of the frequency error information by the frequency error information selection means may be arbitrary. Specifically, for example, it corresponds to a plurality of carriers. A processing order that selects frequency error information that is considered to be highly reliable from the plurality of frequency error information after detecting the plurality of frequency error information for the plurality of signals may be used, or For example, frequency error information about a signal corresponding to the carrier is detected after selecting (not yet detected) frequency error information for a signal corresponding to a carrier regarded as having high reliability of detected frequency error information. Such a processing order may be used.
[0023]
In the frequency error information detection apparatus according to the present invention, in the configuration as described above, as a preferred embodiment, parameter information is acquired and frequency error information is selected as follows.
That is, the parameter information acquisition means, for the signal corresponding to each carrier included in the received signal, the complex correlation value between the data of the predetermined pattern included in the signal and the data of the same pattern as the prepared predetermined pattern Is obtained as parameter information, and the frequency error information selecting means is the frequency error information about the signal corresponding to the carrier from which the maximum complex correlation value is obtained among the plurality of complex correlation values obtained by the parameter information obtaining means. Select.
[0024]
Therefore, for example, parameter information can be obtained by using data of a predetermined pattern included in a communication signal as a unique word or the like in general, which is very effective when applied to general wireless communication. .
[0025]
Specifically, as the complex correlation value between the predetermined pattern data included in the signal corresponding to each carrier and the prepared data of the same pattern is larger, the frequency shift between these two data is larger. Is considered small.
[0026]
Here, as the data of the predetermined pattern, it is preferable to use unique word data as described above, but other data may be used.
Further, as described above, data of the same pattern as the data of the predetermined pattern included in the signal corresponding to each carrier is stored and prepared in advance in the memory of the frequency error information detecting device of the receiving device, for example.
[0027]
Further, in the frequency error information detecting apparatus according to the present invention, in the configuration as described above, as a preferred embodiment, frequency error information for a signal corresponding to each carrier is detected as follows.
That is, the frequency error information detection means is the same pattern as the predetermined pattern in which a predetermined pattern data included in a signal corresponding to each carrier included in the received signal and a frequency offset in the positive direction with respect to the frequency of the carrier are given. And a complex correlation value between the data of the predetermined pattern included in the signal and data of the same pattern as the predetermined pattern obtained by giving a frequency offset in the negative direction with respect to the frequency of the carrier. Based on, frequency error information about the signal is detected.
[0028]
Therefore, for example, when data of a predetermined pattern included in a communication signal is generally used as a unique word or the like, data having the same pattern as the predetermined pattern to which a frequency offset (frequency shift) in the positive direction is given and negative By preparing and using data of the same pattern as the predetermined pattern to which the frequency offset (frequency shift) in the direction is given, it is possible to detect frequency error information for a signal corresponding to each carrier.
[0029]
Specifically, for example, a complex correlation value between data of a predetermined pattern included in a signal corresponding to each carrier and data of the same pattern as the predetermined pattern to which a frequency offset in the positive direction is given, and included in the signal. The ratio of the predetermined correlation data and the complex correlation value between the predetermined pattern data to which the negative frequency offset is applied is obtained. The positive or negative frequency rotation direction of the predetermined pattern data included in the signal is detected from the calculated complex correlation ratio. For example, when positive frequency rotation is detected, the predetermined pattern data and the positive frequency offset are given. A positive phase rotation amount is calculated by phase rotation amount detection calculation from data of the same pattern as the predetermined pattern. The phase rotation amount is obtained as a deviation (error) generated between the frequency of the data of the predetermined pattern included in the signal and the frequency set on the receiving side for the detection.
Here, as described above, it is preferable to use unique word data as the predetermined pattern data, but other data may be used.
[0030]
Further, the frequency error information detection apparatus as described above is suitable for being provided in a reception side apparatus of a wireless communication system that performs multicarrier communication, for example.
In the wireless communication system according to the present invention, a transmission-side device (transmission-side communication device) wirelessly transmits a modulated multicarrier signal, and a reception-side device (reception-side communication device) wirelessly transmits the modulated multicarrier signal. When detecting reception signals corresponding to a plurality of carriers from the modulated multi-carrier signal after detection by the detection frequency signal for each carrier, the receiving side apparatus detects the detection frequency for each carrier as follows. Correct the frequency error for the signal.
That is, the receiving side device includes the frequency error information detecting device as described above, detects a received signal corresponding to a plurality of carriers from the received modulated multicarrier signal, and the frequency error information detecting device uses the frequency error information detecting device. Frequency error information for a received signal corresponding to a carrier considered to have high reliability of frequency error information detected from the received signal corresponding to the carrier of each carrier is selected, and each carrier is selected based on the selected frequency error information. The frequency error of the frequency signal for detection is corrected.
[0031]
Therefore, the frequency error for the frequency signal for detection for each carrier based on the frequency error information that is considered to have high reliability (accuracy) among the plurality of frequency error information for the plurality of received signals corresponding to the plurality of carriers. Is corrected, the accuracy of the correction can be increased, thereby improving the communication quality.
[0032]
Specifically, as a method of correcting the frequency error for the detection frequency signal for each carrier, as an example, the frequency of the detection frequency signal is changed so that the frequency error approaches zero. As another example, by giving the phase rotation component generated in the signal corresponding to each carrier received due to the frequency error between the transmitting and receiving radio units to the reverse phase rotation component A method of approaching zero can be used.
[0033]
Here, as the wireless communication system, for example, various systems such as a mobile phone system and a simple mobile phone system (PHS: Personal Handy phone System) may be used. In addition, as a communication method used for wireless communication, various communication methods such as a CDMA (Code Division Multiple Access) method, a TDMA (Time Division Multiple Access) method, and an FDMA (Frequency Division Multiple Access) method are used. Also good.
[0034]
Various devices may be used as the transmission side device and the reception side device. For example, a base station device, a relay station device, a relay amplification device, a mobile station device, or the like can be used.
Further, as an aspect of correcting the frequency error for the detection frequency signal for each carrier based on the selected frequency error information, for example, for each received signal corresponding to all carriers based on one selected frequency error information A mode for correcting a frequency error for a detection frequency signal for each carrier, or a detection frequency signal for each carrier for reception signals corresponding to all carriers based on, for example, two or more selected frequency error information For example, a mode of correcting a frequency error with respect to can be used.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment according to the present invention will be described with reference to the drawings.
In this example, an example of a frequency error information detection apparatus according to the present invention is shown together by showing an example of a wireless communication system to which the present invention is applied.
Also, in this example, the case where the number of carriers included in the multicarrier communication signal (number of carriers) is 2 (N = 2) is shown. In the following, a signal corresponding to each carrier is referred to as “first carrier communication signal”. "," Second carrier communication signal ". Note that the frequency of the signal corresponding to each carrier differs from one carrier to another.
[0036]
FIGS. 1A and 1B show an example of a digital wireless communication system to which the present invention is applied. FIG. 1A shows a transmission-side communication apparatus provided in the digital wireless communication system. FIG. 2B shows a configuration example of the reception unit of the communication device on the reception side provided in the digital wireless communication system. Note that the receiving-side apparatus includes a circuit that performs processing for correcting a frequency error by an automatic frequency control (AFC) method. In this example, wireless communication is performed between the transmission side device and the reception side device using a communication frame.
[0037]
As shown in FIG. 5A, the transmitting side device includes a unique word (UW1) adding unit 1a, a modulation signal generating unit 2a, and an orthogonal modulation unit 3a as components for processing the first carrier communication signal. Similarly, a unique word (UW2) addition unit 1b, a modulation signal generation unit 2b, and a quadrature modulation unit 3b are provided as components for processing the second carrier communication signal, Further, as components common to the first carrier communication signal and the second carrier communication signal, an adder 4, a radio modulation unit 5, a local oscillation unit 6, a frequency conversion unit 7, a power amplification unit 8, and an antenna 9 is provided.
[0038]
In this example, the configuration and operation of the component parts 1a to 3a that process the first carrier communication signal and the configuration and operation of the component parts 1b to 3b that process the second carrier communication signal are the same. In this example, as the unique word pattern, a common pattern is set in advance between the transmission side device and the reception side device, and is known in advance between the transmission side device and the reception side device. Further, the unique word pattern may be different for each carrier, for example, or a common pattern may be used for two or more carriers.
[0039]
In the transmission side device, first, in order to divide and transmit the data to be transmitted (transmission data) into a plurality of the same time series, the signal of the transmission data is divided into a plurality of transmission signals, and each divided transmission signal The unique word data is added by the unique word adding units 1a and 1b. Here, in this example, the transmission data signal is divided into two transmission signals as described above, and the unique word data is added to one transmission signal by one unique word addition unit 1a, and the other transmission signal is transmitted. On the other hand, the unique word data is added by the other unique word adding unit 1b.
[0040]
Next, in the transmission side device, each transmission signal to which a unique word is added is subjected to modulation processing such as QAM (Quadrature Amplitude Modulation) mapping having I-phase component and Q-phase component by each modulation signal generator 2a, 2b. And performing quadrature modulation by each of the quadrature modulation units 3a and 3b, thereby multiplying the I-phase component and Q-phase component by the local frequency signal and adding the I-phase signal component and the Q-phase signal component. Get the signal. The local frequency is different for each carrier, for example, and the phase is shifted by 90 degrees between the I phase and the Q phase, for example.
[0041]
In the transmission side device, next, the two baseband modulation signals acquired by the two orthogonal modulation units 3a and 3b are added by the adder 4, and the addition result is acquired as a combined baseband modulation signal. A modulation process such as AM (Amplitude Modulation) modulation is performed by the wireless modulation unit 5 in order to wirelessly transmit a band modulation signal, and a communication carrier frequency signal output from the local oscillation unit 6 and a modulation signal obtained by the modulation process Is multiplied by the frequency converter 7 to obtain a modulated signal in a radio frequency (RF) band.
Next, in the transmission side apparatus, the RF modulation signal acquired by the frequency conversion unit 7 is amplified by the power amplification unit 8, and the amplification result is transmitted to the wireless space by the antenna 9.
[0042]
On the other hand, as shown in FIG. 5B, the receiving side device includes an antenna 11, a high frequency amplifying unit 12, and a first local unit as components common to the first carrier communication signal and the second carrier communication signal. The oscillator 13, the first frequency converter 14, the second local oscillator 15, the second frequency converter 16, the radio demodulator 17, and the AFC controller 20 are provided, and the first As a component for processing the carrier communication signal, an orthogonal detection unit 18a, an AFC processing unit 19a, a synchronization processing unit 21a, an equalization processing unit 22a, and a demodulated data generation unit 23a are provided. As components for processing the second carrier communication signal, an orthogonal detector 18b, an AFC processor 19b, a synchronization processor 21b, an equalization processor 22b, and a demodulated data generator 23b are provided.
[0043]
In this example, the configuration and operation of the component parts 18a, 19a, and 21a to 23a that process the first carrier communication signal, and the configuration and operation of the component parts 18b, 19b, and 21b to 23b that process the second carrier communication signal. Is the same.
[0044]
In the reception side device, first, the RF modulation signal modulated from the transmission side device and transmitted by radio as described above is received by the antenna 11 as an RF reception signal.
Next, in the reception side device, the RF reception signal is amplified by the high frequency amplification unit 12, and then the first communication carrier frequency signal output from the first local oscillation unit 13 and the RF reception signal are converted into the first frequency conversion unit. 14 to obtain a received signal in an intermediate frequency (IF) band, and a second frequency conversion is performed on the second communication carrier frequency signal output from the second local oscillator 15 and the IF received signal. Multiplication is performed by the unit 16, and a reception signal as a result of the multiplication is demodulated by the radio demodulation unit 17 to obtain a reception signal in a baseband (BB) band.
[0045]
Next, in the receiving-side apparatus, the acquired baseband band received signals are distributed into two, which is the same as the number of carriers, corresponding to each distributed signal and each carrier (first carrier communication signal, second carrier communication signal). The quadrature detection processing is performed by multiplying the signals of the local frequency by the quadrature detection units 18a and 18b. Here, the frequency error for each local frequency is corrected by the frequency error correction value calculated and controlled by the AFC control unit 20 using the frequency error information calculated by each AFC processing unit 19a, 19b, as will be described later. Is done. In this example, one orthogonal detector 18a uses the local frequency corresponding to the first carrier communication signal to detect the first carrier communication signal, and the other orthogonal detector 18b uses the local frequency corresponding to the second carrier communication signal. The second carrier communication signal is detected using the frequency.
[0046]
In the receiving apparatus, as will be described later, each AFC processing unit 19a, 19b acquires parameter information and frequency error information for signals corresponding to each carrier (first carrier communication signal, second carrier communication signal). The AFC control unit 20 selects one frequency error information from the two frequency error information based on the acquired two parameter information, and the AFC control unit 20 selects each frequency error information based on the frequency error information selected by the AFC control unit 20. The frequency error of the local frequency for detection used in the quadrature detection units 18a and 18b is corrected. Details of configuration examples and operation examples of the AFC processing units 19a and 19b and details of configuration examples and operation examples of the AFC control unit 20 will be described with reference to FIG.
[0047]
Next, in the receiving side device, the unique word part in the received signal of each carrier separated into the I phase and the Q phase by the quadrature detection by each of the quadrature detection units 18a and 18b and the preset in the receiving side device are prepared in advance. The complex correlation calculation with the known unique word pattern is performed by each synchronization processing unit 21a, 21b, and for example, the synchronization point of the received signal for each carrier is calculated based on the complex correlation calculation timing at which the complex correlation value is maximized, Thereafter, equalization processing is performed by the equalization processing units 22a and 22b, and demodulated data generation processing such as QAM demapping is performed by the demodulated data generation units 23a and 23b to acquire demodulated data for each carrier. Then, the receiving side apparatus combines the acquired demodulated data divided and transmitted by the transmitting side apparatus, and acquires the data before the division.
[0048]
Next, configuration examples and operation examples of the above-described AFC processing units 19a and 19b and configuration examples and operation examples of the above-described AFC control unit 20 will be described in detail.
FIG. 2 shows a quadrature detection unit 31a for processing a first carrier communication signal and an optimum reception sequence as a configuration example of a circuit that performs automatic frequency control provided in the reception-side apparatus shown in FIG. Selection parameter calculator 32a and frequency error calculator 33a, quadrature detector 31b for processing the second carrier communication signal, optimum received sequence selection parameter calculator 32b and frequency error calculator 33b, first carrier communication signal and An optimum reception sequence selection unit 34, frequency error control unit 35, and error correction value calculation unit 36 common to the second carrier communication signal are shown.
[0049]
Here, the two quadrature detection units 31a and 31b correspond to the two quadrature detection units 18a and 18b shown in FIG. 1B, and the optimum reception sequence selection parameter calculation unit 32a corresponding to the first carrier communication signal and The frequency error calculation unit 33a corresponds to the function of the AFC processing unit 19a corresponding to the first carrier communication signal shown in FIG. 1B, and the optimum reception sequence selection parameter calculation unit 32b corresponding to the second carrier communication signal; The frequency error calculation unit 33b corresponds to the function of the AFC processing unit 19b corresponding to the second carrier communication signal shown in FIG. 1B, and the optimum reception sequence selection unit 34, the frequency error control unit 35, and the error correction value calculation. The unit 36 corresponds to the function of the AFC control unit 20 shown in FIG.
[0050]
An example of the operation of the circuit shown in FIG.
In the circuit shown in the figure, first, each distributed baseband received signal is subjected to quadrature detection by the quadrature detection units 31a and 31b and separated into an I-phase signal and a Q-phase signal.
Next, in each optimum reception sequence selection parameter calculation unit 32a, 32b, the unique word portion of the baseband reception signal of each reception sequence (each carrier) separated into the I phase and the Q phase corresponds to each of these reception sequences. Then, a complex correlation calculation with a unique word pattern preset in the receiving side device is performed, and the complex correlation calculation result for each reception sequence is used as an optimal reception sequence selection parameter for each reception sequence to the optimal reception sequence selection unit 34 Output.
[0051]
Then, in the optimum reception sequence selection unit 34, the magnitude of the optimum reception sequence selection parameter for each input reception sequence is compared, and the reception sequence having the maximum value for the inputted optimum reception sequence selection parameter is selected. The frequency error control unit 35 is notified of the selection result.
[0052]
Further, in each frequency error calculation unit 33a, 33b, the unique word part of the baseband reception signal of each reception sequence (each carrier) separated into the I phase and the Q phase, and the reception side corresponding to each reception sequence By calculating a complex correlation with a unique word pattern intentionally given a frequency offset in both positive and negative directions preset in the device, information on the frequency error for each received sequence is calculated, and then for each received sequence The calculation result is output to the frequency error control unit 35 as a calculated value of the frequency error information for each reception series. Details of the calculation of the frequency error information will be described with reference to FIG. 3 described later.
[0053]
Next, the frequency error control unit 35 obtains the reception sequence selected by the optimum reception sequence selection unit 34 from the frequency error information for each reception sequence input from the frequency error calculation units 33a and 33b. The frequency error information is selected as having the highest reliability (accuracy), and the selected frequency error information is output to the error correction value calculation unit 36.
[0054]
Next, in the error correction value calculation unit 36, based on the input frequency error information, for example, by performing control related to the local frequency used in the quadrature detection in the quadrature detection units 31a and 31b of the two reception sequences, the frequency error is calculated. A frequency error correction value for correction is calculated, and the calculation result is output to the two quadrature detection units 31a and 31b.
In each quadrature detection unit 31a, 31b, the input frequency error correction value controls, for example, the amount of rotation of the reverse phase given to the reception signal for each reception sequence in the quadrature detection of the next reception frame. Used as information.
[0055]
Next, a configuration example and an operation example of a circuit for performing automatic frequency control by the correlation peak detection type AFC method will be described with reference to FIG.
In the figure, as a configuration example of a circuit for performing such automatic frequency control, a quadrature detection unit 41 corresponding to one carrier, a unique word generation unit 42a corresponding to a frequency offset in the positive direction, and a complex correlation calculation Unit 43a and power calculation unit 44a, unique word generation unit 42b corresponding to negative frequency offset, complex correlation calculation unit 43b and power calculation unit 44b, power common to positive frequency offset and negative frequency offset A ratio calculation unit 45, a frequency error detection unit 46, a frequency error conversion unit 47, and an averaging processing unit 48 are shown.
[0056]
Here, the quadrature detection unit 41 corresponds to one of the quadrature detection unit 31a or the quadrature detection unit 31b shown in FIG. 2, and the two unique word generation units 42a and 42b and the two complex correlation calculation units 43a, 43b and 2 The two power calculation units 44a and 44b, the power ratio calculation unit 45, and the frequency error detection unit 46 correspond to one function of the frequency error calculation unit 33a or the frequency error calculation unit 33b shown in FIG. The averaging processing unit 48 corresponds to the function of the error correction value calculation unit 36 shown in FIG.
[0057]
In FIG. 3, in order to simplify the description, the frequency error for the local frequency used by the quadrature detection unit 41 for one carrier is corrected based on the frequency error information detected for the one carrier. A configuration example is shown. When the configuration shown in FIG. 3 is applied to the circuit shown in FIG. 2, the configuration shown in FIG. 3 is applied to the circuit shown in FIG. It is configured to include the functions of the optimum reception sequence selection parameter calculation units 32a and 32b, the function of the optimum reception sequence selection unit 34, and the function of the frequency error control unit 35.
[0058]
An operation example of the circuit shown in FIG. 3 is shown.
In the circuit shown in the figure, first, the baseband received signal is quadrature detected by the quadrature detection unit 41 and separated into the I-phase signal and Q-phase signal of the carrier corresponding to the quadrature detection unit 41, and the separated I-phase signal is separated. The signal and the Q-phase signal are output to the two complex correlation operation units 43a and 43b.
[0059]
In the unique word generating unit 42a corresponding to the frequency offset in the positive direction, for example, with respect to the frequency of the carrier (unique word) when the frequency shift between the transmission side device and the reception side device is zero (none) Then, a unique word pattern having a frequency offset (for example, a frequency shift of + f [Hz]) in the positive direction is generated and output to the complex correlation calculation unit 43a.
[0060]
Similarly, in the unique word generation unit 42b corresponding to the frequency offset in the negative direction, for example, when the frequency shift between the transmission side apparatus and the reception side apparatus is zero (no), the carrier (unique word) A unique word pattern having a frequency offset (for example, a frequency shift of −f [Hz]) in a negative direction with respect to the frequency is generated and output to the complex correlation calculation unit 43b.
[0061]
Next, in each of the complex correlation calculation units 43a and 43b, a unique word unit included in the baseband reception signal composed of the separated I-phase signal and Q-phase signal input from the quadrature detection unit 41, and each unique word generation unit The complex correlation value with the unique word pattern frequency-offset in the positive and negative directions input from 42a and 42b is calculated, and the calculation result is output to each power calculation unit 44a and 44b. Next, each power calculation unit 44a, 44b calculates a complex correlation square sum (sequence square sum) as each power value based on the complex correlation sequence input from each complex correlation calculation unit 43a, 43b, and the calculation result Is output to the power ratio calculation unit 45.
[0062]
Here, specifically, for example, the unique word data included in the baseband received signal is (a (n) + j · b (n)), and the unique word pattern is frequency offset in the positive or negative direction. Assuming that the data of (c (n) + j · d (n)) is given, the complex correlation square sum Z is expressed as shown in Equation 1. Note that n = 0, 1, 2,..., P, and p is an arbitrary plurality. J represents an imaginary part.
[0063]
Further, the data of the unique word in the received signal is composed of (p + 1) data values, a (n) indicates the value of the real part of the nth data value constituting the unique word data, and b (N) indicates the value of the imaginary part of the nth data value constituting the unique word data. Similarly, the frequency-offset unique word data is composed of (p + 1) data values, and c (n) indicates the value of the real part of the nth data value constituting the unique word data. , D (n) indicates the value of the imaginary part of the nth data value constituting the unique word data.
[0064]
[Expression 1]

[0065]
Next, the power ratio calculation unit 45 calculates a ratio (positive / negative complex correlation ratio) between the two power values input from the two power calculation units 44 a and 44 b and outputs the calculation result to the frequency error detection unit 46. .
Next, the frequency error detection unit 46 detects a frequency error based on the positive / negative complex correlation ratio input from the power ratio calculation unit 45, generates frequency error information from the detection result, and outputs the frequency error information to the frequency error conversion unit 47. To do.
[0066]
Next, the frequency error conversion unit 47 generates control information for performing control related to the local frequency used in the quadrature detection in the quadrature detection unit 41 based on the input frequency error information, and averages the generated control information The data is output to the processing unit 48.
Next, in the averaging processing unit 48, the input control information is averaged, thereby absorbing and reducing a large deviation in the calculation result predicted to occur suddenly, for example. Control information is given to the quadrature detection unit 41.
[0067]
As the control information, for example, information on an offset frequency (for example, the magnitude of the frequency shift and the positive / negative direction) for correcting a frequency error for the local frequency used in the quadrature detection unit 41 can be used. .
[0068]
Here, an example of an arithmetic expression for averaging the control information is shown in Expression 2. It is assumed that the control information is averaged over M (M is a plurality) of control information, Xave is an averaged result of the control information up to the previous time, and Xave ′ includes the current control information. Xt is control information calculated in the current (current) frame, and λ is a forgetting coefficient such that 0 <λ <1.
[0069]
[Expression 2]

[0070]
Then, in the quadrature detection unit 41, for example, in the quadrature detection of the next received frame, the input control information controls the amount of rotation of the reverse phase given to the reception signal of the carrier corresponding to the quadrature detection unit 41 This is used as information on the frequency error correction value, and thereby the frequency error is corrected.
[0071]
As described above, in the wireless communication system of this example, for example, a transmission signal sequence having a frame configuration in which a signal (unique word) having a predetermined pattern is added for each transmission data having a predetermined length is used. In a transmission system in which a modulated signal obtained by modulating such a transmission signal sequence by the transmission side is wirelessly transmitted from the transmission side and the transmission signal sequence is demodulated from the modulation signal received by the reception side. The following processing is performed on the transmission side and the reception side.
[0072]
That is, on the transmission side, when there are N (N ≧ 2) transmission signal sequences as described above, each transmission signal sequence is orthogonally modulated with N different local frequencies, and N signals obtained by the orthogonal modulation are obtained. The modulated signals (N carrier signals after modulation) are combined, and the combined result is wirelessly transmitted as a modulated multicarrier signal.
[0073]
On the other hand, on the receiving side, the combined modulated signal transmitted wirelessly from the transmitting side is received, and the received signal is orthogonally detected by the same frequency as the N different local frequencies. And calculates parameters for each received signal sequence used to select the most reliable received signal sequence having the highest reliability among the N received signal sequences after the orthogonal detection, and after the orthogonal detection, Calculate frequency error information for each received signal sequence from N received signal sequences, compare the calculated parameters, select frequency error information for the optimal received signal sequence, and select the selected frequency error information. Based on this, for example, a value for correcting the frequency error included in the N received signal sequences is calculated, and the calculated correction value of the frequency error is input to the functional unit that performs the quadrature detection. To correct the frequency error based on.
[0074]
Further, in the wireless communication system of this example, as a preferred embodiment, each unique word part in N received signal sequences after quadrature detection and a unique word preset on the receiving side corresponding to each unique word part are provided. A complex correlation calculation with the pattern is performed, and the complex correlation value obtained for each received signal sequence is used as an optimum received sequence selection parameter for each received signal sequence.
[0075]
Further, as a preferred example of the receiving side of the wireless communication system of the present example, each unique word part in N received signal sequences after quadrature detection is set in advance on the receiving side corresponding to each unique word part. Then, a complex correlation calculation with a unique word pattern intentionally given a frequency offset in both positive and negative directions is performed, and frequency error information for each received signal sequence is calculated based on the calculation result.
[0076]
In the wireless communication system of the present example, as a preferred embodiment, for example, in a configuration capable of transmitting a digital information signal by performing automatic frequency control, between the wireless device on the transmission side and the wireless device on the reception side. The phase rotation component of the received signal on the receiving side due to the generated carrier frequency shift is corrected. Note that the correction of the frequency deviation can be performed by, for example, a method of rotating the phase of the received signal reversely or a method of adjusting the local frequency, for example.
[0077]
As described above, in the wireless communication system of this example, the optimum one is selected from the frequency error information for the N received signal sequences, and the locality of the N orthogonal detectors is selected based on the selected frequency error information. A frequency error due to a carrier frequency shift between the transmitting and receiving radios is detected based on N transmission signal sequences by a method of performing a control for correcting a frequency shift related to the frequency, and thereby, for example, more accurate than in the past. It becomes possible to correct the frequency error for each transmission signal series by using the correction value of the frequency error, so that the communication quality can be improved.
[0078]
Here, in this example, the frequency error information detection means is configured by the function of the frequency error calculation units 33a and 33b, and the parameter information acquisition unit is configured by the function of the optimum reception sequence selection parameter calculation units 32a and 32b. The function of the optimum reception sequence selection unit 34 and the function of the frequency error control unit 35 constitute frequency error information selection means, and these function means constitute the function of the frequency error information detection device.
[0079]
In this example, the optimum reception sequence selection parameter that is a complex correlation value for a unique word is used as parameter information that reflects the reliability of detected frequency error information.
In this example, unique word data is used as data of a predetermined pattern.
In this example, the local frequency signal used for quadrature detection in the quadrature detection units 31a and 31b corresponding to each carrier is used as the detection frequency signal for each carrier.
[0080]
Also, in this example, the phase rotation component of the reception signal in the reception side device due to the carrier frequency shift occurring between the transmission side device and the reception side device is corrected, or the orthogonality corresponding to each carrier By correcting the local frequency used for quadrature detection in the detectors 31a and 31b, the frequency error of the detection frequency signal for each carrier is corrected.
[0081]
Here, the configurations of the frequency error information detection device, the wireless communication system, the transmission side device, the reception side device, and the like according to the present invention are not necessarily limited to those described above, and various configurations may be used.
The application field of the present invention is not necessarily limited to the above-described fields, and the present invention can be applied to various fields.
[0082]
In addition, as various processes performed in the frequency error information detection apparatus, the radio communication system, the transmission side apparatus, the reception side apparatus, and the like according to the present invention, for example, in a hardware resource including a processor, a memory, etc. A configuration controlled by executing a control program stored in (Only Memory) may be used, and for example, each functional unit for executing the processing may be configured as an independent hardware circuit. .
Further, the present invention can be grasped as a computer-readable recording medium such as a floppy (registered trademark) disk or a CD (Compact Disc) -ROM storing the above control program, or the program (itself). The processing according to the present invention can be performed by inputting a control program from a recording medium to a computer and causing it to be executed by a processor.
[0083]
【The invention's effect】
As described above, according to the frequency error information detection apparatus and the like according to the present invention, when detecting information on a frequency error for a signal received by multicarrier communication, a signal corresponding to each carrier included in the received signal is detected. Information on the frequency error of the signal is detected based on the parameter, and parameter information reflecting the reliability of the frequency error information detected based on the signal corresponding to each carrier included in the received signal is acquired and acquired. The frequency error information for a signal corresponding to a carrier that is considered to have high reliability in frequency error information detected based on a plurality of parameter information is selected, so that such reliability is high and accuracy is high. By applying frequency error information regarded as It is possible to Ku correction.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an example of a wireless communication system.
FIG. 2 is a diagram illustrating an example of a circuit that performs automatic frequency control according to an embodiment of the present invention.
FIG. 3 is a diagram for explaining an example of the configuration of a circuit for performing automatic frequency control.
FIG. 4 is a diagram illustrating an example of a circuit that performs automatic frequency control according to a conventional example.
[Explanation of symbols]
1a, 1b... Unique word addition unit, 2a, 2b... Modulation signal generation unit,
3a, 3b ··· quadrature modulator, ··· adder, 5 · · radio modulator,
6, 13, 15 ... Local oscillator, 7, 14, 16 ... Frequency converter,
8 .. Power amplifying part 9, 11 .. Antenna 12.. High frequency amplifying part
17 ··· Wireless demodulation unit, 18a, 18b · · Quadrature detection unit,
19a, 19b ··· AFC processing unit, 20 ·· AFC control unit,
21a, 21b .. synchronization processing unit, 22a, 22b .. equalization processing unit,
23a, 23b .. demodulated data generator,

Claims (3)

A frequency error information detection device that detects information about a frequency error for a signal received by multicarrier communication,
Frequency error information detecting means for detecting information on the frequency error of the signal based on a signal corresponding to each carrier included in the received signal;
Parameter information acquisition means for acquiring parameter information reflecting the reliability of the frequency error information detected by the frequency error information detection means, based on a signal corresponding to each carrier included in the received signal;
A frequency for selecting frequency error information for a signal corresponding to a carrier that is considered to have high reliability of the frequency error information detected by the frequency error information detecting unit based on a plurality of parameter information acquired by the parameter information acquiring unit. Error information selection means ,
The parameter information acquisition means sets, for a signal corresponding to each carrier included in the received signal, a parameter of a complex correlation value between the predetermined pattern data included in the signal and the prepared data of the same pattern as the predetermined pattern. As information,
The frequency error information selection unit selects frequency error information for a signal corresponding to the carrier from which the maximum complex correlation value is acquired among the plurality of complex correlation values acquired by the parameter information acquisition unit.
A frequency error information detection apparatus characterized by the above. In the frequency error information detecting device according to claim 1 ,
The frequency error information detection means includes data of a predetermined pattern included in a signal corresponding to each carrier included in the received signal and data of the same pattern as the predetermined pattern in which a frequency offset in the positive direction is given to the frequency of the carrier. And a complex correlation value between the data of the predetermined pattern included in the signal and the data of the same pattern as the predetermined pattern obtained by giving a negative frequency offset to the frequency of the carrier. To detect frequency error information about the signal,
A frequency error information detection apparatus characterized by the above. The transmitting side apparatus transmits the modulated multicarrier signal by radio, and the receiving side apparatus receives the modulated multicarrier signal by radio, and then transmits the modulated multicarrier signal to a plurality of carriers by the detection frequency signal for each carrier. In a wireless communication system that detects a corresponding received signal,
The frequency error information detection device according to claim 1 or 2 is provided in a reception side device,
The receiving side device detects the received signal corresponding to a plurality of carriers from the received modulated multicarrier signal, and the frequency error information detected from the received signals corresponding to the plurality of carriers by the frequency error information detecting device. Selecting frequency error information about a received signal corresponding to a carrier considered to have high reliability, and correcting a frequency error about a detection frequency signal for each carrier based on the selected frequency error information.
A wireless communication system.

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