JP2008526157A - Signal transmitting and receiving apparatus and method for high-speed frequency hopping-orthogonal frequency division communication system - Google Patents

Abstract

  The present invention provides a pre-configured transmission of input data in an FFH-OFDM communication system that divides the entire frequency band into multiple subcarrier bands and includes multiple subchannels that are a collection of one or more subcarrier bands. The null data is inserted into the subcarriers excluding the predetermined number of subcarriers, the input data is input so as to correspond one-to-one with the set number of subcarriers, and the subcarrier signal with the null data inserted is input in advance. After performing high-speed frequency hopping so as to correspond to the set high-speed frequency hopping pattern, the high-speed frequency hopped signal is fast Fourier transformed, null data is inserted into subcarriers excluding the set number of subcarriers, and then high speed A set number of Fourier-transformed subcarrier signals and null data were inserted in the fourth process. Inverse fast Fourier transform to input sub-carrier signals excluding the sub-carrier of a constant number, and transmits the inverse fast Fourier transformed signal.

Description

  The present invention relates to a communication system that uses a fast frequency hopping (FFH) method and an orthogonal frequency division multiplexing (hereinafter referred to as “OFDM”) method (hereinafter, “fast frequency hopping-OFDM communication”). In particular, the present invention relates to an apparatus and a method for transmitting and receiving signals using only a part of a whole frequency band used in a high-speed frequency hopping-OFDM communication system.

In a 4 ^th generation (hereinafter referred to as “4G”) mobile communication system, which is a next generation communication system, services having various quality of service (hereinafter referred to as “QoS”) can be provided at high speed. Active research to provide to users is progressing. Accordingly, in the current 4G mobile communication system, a wireless local area network (hereinafter referred to as “LAN”) system and a wireless urban area network (hereinafter referred to as “MAN”) that ensure a relatively high transmission rate. Research on the development of a new communication system for ensuring mobility and QoS in a system (referred to as') and supporting high-speed services is actively progressing.

  OFDM and Orthogonal Frequency Division Multiple Access (hereinafter referred to as “OFDMA”) are actively used to support a broadband transmission network in the physical channel of a wireless MAN system. It is a trend that is being used. In the OFDM / OFDMA scheme, a physical channel signal is transmitted using a number of sub-carriers, so that high-speed data transmission is possible, and the frequency bands in which signals are transmitted are different from each other. By using this, a frequency diversity gain can be obtained.

  Compared to a system using a single subcarrier, an OFDM communication system has a symbol period higher than that using a single subcarrier at the same data transmission rate because of the use of multiple subcarriers. When the guard interval is used, the length increases in proportion to the number of subcarriers, and a radio channel having multipath fading is referred to as “Inter Symbol Interference” (hereinafter referred to as “ISI”). ) Can be reduced. For example, the guard interval may be a guard interval inserted by a 'cyclic prefix' scheme in which the last constant sample of a time-domain OFDM symbol is copied and inserted into an effective OFDM symbol, or time is used. It is possible to use a guard interval inserted by a 'cyclic postfix' scheme in which the first constant sample of the OFDM symbol in the region is copied and inserted into the effective OFDM symbol.

）設定することによって、１つのＯＦＤＭシンボル周期の間、キャリヤ間干渉（Inter Carrier Interference；以下、‘ＩＣＩ’と称する）の影響を減少させることができる。サブキャリヤが直交して干渉の影響が存在しない場合、ＯＦＤＭ通信システムの受信機では比較的簡単な単一タップ（tap）等化器のみを使用してデータを復調することができる。また、ＯＦＤＭ通信システムは、逆高速フーリエ変換（Inverse Fast Fourier Transform；以下、‘ＩＦＦＴ’と称する）方式及び高速フーリエ変換（Fast Fourier Transform；以下、‘ＦＦＴ’と称する）方式を使用して多数のサブキャリヤを変復調するので、システムの複雑度を最小化することができる。ＩＦＦＴ方式を使用する逆高速フーリエ変換器（以下、‘ＩＦＦＴ器’と称する）の動作は、ＯＦＤＭ通信システムにおける周波数変調動作に該当するものであり、これは、下記の＜数式１＞に表した行列

で表現可能である。 Further, the channel response of each subcarrier band is approximated in a flat form within the subcarrier band, and the difference (Δf) between the subcarrier frequencies is the inverse of the sampling period (T _s ). To be several times (

By setting, the influence of inter carrier interference (hereinafter referred to as “ICI”) can be reduced during one OFDM symbol period. If the subcarriers are orthogonal and there is no interference effect, the receiver of the OFDM communication system can demodulate the data using only a relatively simple single tap equalizer. The OFDM communication system uses an inverse fast Fourier transform (hereinafter referred to as 'IFFT') method and a fast Fourier transform (hereinafter referred to as 'FFT') method. Since the subcarrier is modulated and demodulated, the complexity of the system can be minimized. The operation of the inverse fast Fourier transformer (hereinafter referred to as “IFFT device”) using the IFFT method corresponds to the frequency modulation operation in the OFDM communication system, which is expressed by the following <Formula 1>. line; queue; procession; parade

It can be expressed as

は大きさがＱ×ＱのＩＦＦＴ行列を表す。ここで、サブチャネルとは、少なくとも１つ以上のサブキャリヤで構成されるチャネルを意味する。また、上記ＩＦＦＴ器に対応する、上記ＦＦＴ方式を使用する高速フーリエ変換器（以下、‘ＦＦＴ器’と称する）の動作は、上記の＜数式１＞に表したＩＦＦＴ行列

のハーミシアン（Hermitian）

で表現可能である。 In Equation 1, Q represents the number of total subcarriers used in the OFDM communication system, n represents a sample index, and m represents a sub-channel index. As a result, the above

Represents an IFFT matrix of size Q × Q. Here, the subchannel means a channel composed of at least one or more subcarriers. The operation of the fast Fourier transform (hereinafter referred to as “FFT unit”) corresponding to the IFFT unit and using the FFT method is the IFFT matrix expressed by the above-described <Equation 1>.

Hermitian

It can be expressed as

  On the other hand, as described above, when there is a subcarrier that experiences a dip fading phenomenon among a number of subcarriers in an OFDM communication system, data transmitted through the subcarrier that experiences the dip fading phenomenon. The probability of normal demodulation at the receiver is low. As methods proposed to overcome the performance degradation due to the dip fading phenomenon, there are a frequency hopping method and a forward error correction (FEC) method.

  The frequency hopping method is a method of changing the frequency band in which a signal is transmitted according to a preset frequency hopping pattern (pattern), and can obtain an average gain of inter-cell interference. It is a method. That is, the above-described frequency hopping scheme transmits signals while periodically changing the transmission frequency band according to the frequency hopping pattern for the subcarriers periodically at a preset time, so that an arbitrary frequency can be selected depending on the frequency selective channel characteristics. It is possible to prevent a single user from transmitting a signal through a subcarrier that continuously experiences the dip fading phenomenon. Here, the frequency hopping period is the time corresponding to the OFDM symbol time or a constant multiple of the OFDM symbol. As a result, when using a frequency hopping scheme, even if a signal is transmitted to a user through a subcarrier that experiences a dip fading phenomenon at any OFDM symbol time, the dip fading phenomenon occurs at the next OFDM symbol time. By transmitting a signal through an unexperienced subcarrier, frequency diversity gain and interference can be averaged without being affected by the current dip fading current state.

  In addition, according to the FH-OFDM scheme, which combines the frequency hopping scheme and the OFDM scheme, the FH-OFDM scheme allocates different subchannels to each of the users, and sets the subchannels allocated to each of the users in advance. In this method, frequency diversity gain and interference averaging gain between adjacent cells can be obtained by performing frequency hopping.

  However, in a conventional OFDM communication system, in order to obtain a sufficient gain by the frequency hopping method, it is necessary to perform frequency hopping over a number of OFDM symbol times, and the number of users must be large, and depending on the channel. There is a problem that there is a limitation that an appropriate frequency hopping pattern has to be selected. In addition, in the conventional OFDM communication system, when the frequency hopping method is used, a signal is not transmitted to a single user through a subcarrier that continuously experiences the dip fading phenomenon, but the dip is performed every OFDM symbol time. The signal transmitted through the subcarrier that experiences the fading phenomenon still has the problem that it cannot be demodulated by the receiver.

  Therefore, in order to be able to demodulate the transmitted signal by experiencing dip fading at the receiver, signals are transmitted / received using subcarriers of all frequency bands possible in the FFH-OFDM communication system. What is needed is an improved method and apparatus for achieving this.

  An object of the present invention is to provide an apparatus and method for transmitting and receiving signals in a high-speed frequency hopping-OFDM communication system.

  It is another object of the present invention to provide an apparatus and method for performing high-speed frequency hopping using only a part of a total frequency band used in a high-speed frequency hopping-OFDM communication system.

  The apparatus of the present invention for achieving the aforementioned object divides all usable frequency bands into a number of subcarrier bands, and has a high frequency with a number of subchannels composed of one or more subcarrier bands. A signal transmitting apparatus of a hopping-orthogonal frequency division multiplexing (FFH-OFDM) communication system, wherein input data is converted into the number of subcarriers selected from all the usable subcarriers. A fast frequency hopping device that performs fast frequency hopping with a fast frequency hopping signal generated by a fast frequency hopping pattern, a fast Fourier transform that fast Fourier transforms the fast frequency hopping signal, and the remaining A controller that inserts null data into the subcarrier and an input data A first inverse fast Fourier transformer configured to perform an inverse fast Fourier transform on the remaining subcarriers, to which the selected subcarrier and the null data are input, and a first inverse fast Fourier transform signal; And a transmitter for transmitting.

  Another apparatus of the present invention for achieving the aforementioned object divides all available frequency bands into a number of subcarrier bands and comprises a number of subchannels that are a collection of one or more subcarrier bands. A signal transmission apparatus of a Fast Frequency Hopping-Orthogonal Frequency Division Multiplexing (FFH-OFDM) communication system, a first fast Fourier transformer that performs fast Fourier transform on a received signal, and a first The transmitting apparatus separates the remaining subcarriers excluding the selected subcarrier from the plurality of subcarriers by using the signal subjected to the fast Fourier transform by the fast Fourier transformer, and corresponds to the remaining subcarriers. Are equalized by a controller that inserts null data into the controller, a first equalizer that equalizes the output signal of the controller in the frequency domain, and a first equalizer. An inverse fast Fourier transformer that performs inverse fast Fourier transform so as to correspond to the fast frequency hopping matrix applied by the transmitter, and a second equalizer that equalizes the signal subjected to inverse fast Fourier transform in the time domain, And a second fast Fourier transformer for fast Fourier transforming the signal equalized in the time domain.

  Still another apparatus of the present invention for achieving the above-mentioned object divides all usable frequency bands into a number of subcarrier bands, and a number of subchannels that are a set of one or more subcarrier bands. A signal transmission device of a Fast Frequency Hopping-Orthogonal Frequency Division Multiplexing (FFH-OFDM) communication system comprising input data among all the usable subcarriers. A first controller that inserts null data into the remaining subcarriers at the selected subcarrier, and assigns input data to the number of subcarriers selected from all the available subcarriers for high speed transmission. High frequency hopping with high frequency hopping signal generated by frequency hopping pattern A selected subcarrier signal comprising a frequency hopping device, a fast Fourier transform for fast Fourier transforming the fast frequency hopped signal, a second controller for inserting null data into the remaining subcarriers, and input data And a first inverse fast Fourier transform that performs an inverse fast Fourier transform by inputting the remaining subcarrier signal into which the null data has been inserted so as to generate a first IFFT signal, and a first inverse fast Fourier transform And a transmitter for transmitting a signal.

  Still another apparatus of the present invention for achieving the above-mentioned object divides all usable frequency bands into a number of subcarrier bands, and a number of subchannels that are a set of one or more subcarrier bands. A signal transmission device of a Fast Frequency Hopping-Orthogonal Frequency Division Multiplexing (FFH-OFDM) communication system, comprising: a first fast Fourier transformer that performs a fast Fourier transform on a received signal; The transmission apparatus separates the remaining subcarriers except for the selected subcarrier, which transmitted the data, among the plurality of subcarriers, using the signal subjected to the fast Fourier transform by one fast Fourier transformer, and the remaining subcarriers. A first controller for inserting null data so as to correspond to the subcarrier; and a first controller for equalizing the output signal of the first controller in the frequency domain An inverse fast Fourier transformer that performs inverse fast Fourier transform on the signal equalized in the frequency domain corresponding to the fast frequency hopping matrix applied to the transmission device, and time-domain signal that has been inverse fast Fourier transformed A second equalizer that equalizes the signal, a second fast Fourier transformer that performs a fast Fourier transform on the signal equalized in the time domain, and a signal obtained by performing a fast Fourier transform on the second fast Fourier transformer. And a second controller for separating null sub-carriers and inserting null data into the remaining sub-carriers.

  The method of the present invention for achieving the above-described object is to divide all available frequency bands into a number of subcarrier bands and to provide a high frequency with a number of subchannels that are a collection of one or more subcarrier bands. A signal transmission method for a hopping-orthogonal frequency division multiplexing (OFDM) communication system, wherein input data is assigned to a number of subcarriers selected from all the available subcarriers, Performing fast frequency hopping with the fast frequency hopping signal generated by the fast frequency hopping pattern, fast Fourier transforming the fast frequency hopping signal, and inserting null data into the remaining subcarriers after selection Selected subcarriers composed of input data and the Performing a reverse fast Fourier transform to generate a first inverse fast Fourier transform signal for the remaining subcarriers with data input, and transmitting a first inverse fast Fourier transform signal; It is characterized by.

  Another method of the present invention for achieving the above-mentioned object divides all available frequency bands into a number of sub-carrier bands and comprises a number of sub-channels that are a collection of one or more sub-carrier bands. A signal transmission method for a Fast Frequency Hopping-Orthogonal Frequency Division Multiplexing (FFH-OFDM) communication system, which includes a first process for fast Fourier transform of a received signal, and a first process in the first process. The signal transmitted from the Fast Fourier Transformer of the first Fourier transform is separated from the signals corresponding to the remaining subcarriers, excluding the selected subcarriers, from among the multiple subcarriers transmitted by the transmitter. A second step of inserting null data into the remaining subcarriers; a third step of equalizing the signal generated in the second step in the frequency domain; A fourth process for performing inverse fast Fourier transform on the signal equalized in the frequency domain by the fast frequency hopping matrix, a fifth process for equalizing the signal subjected to inverse fast Fourier transform in the time domain, and equalized in the time domain And a sixth process of fast Fourier transforming the signal.

  Yet another method of the present invention for achieving the above-described object is to divide all available frequency bands into a number of subcarrier bands, and to divide a number of subchannels that are a collection of one or more subcarrier bands. A signal transmission method of a Fast Frequency Hopping-Orthogonal Frequency Division Multiplexing (FFH-OFDM) communication system comprising: input data out of all the usable subcarriers; A first step of transmitting data, inserting null data into the remaining subcarriers excluding the selected subcarrier, and assigning input data to the number of subcarriers selected from all the available subcarriers; Fast frequency hopping is achieved with the fast frequency hopping signal generated by the fast frequency hopping pattern. A second process, a third process for fast Fourier transforming the fast frequency hopped signal, a fourth process for inserting null data into the remaining subcarriers with the fast Fourier transformed signal, and a fast Fourier transform A fifth process in which the selected subcarrier signal and the remaining subcarrier signal into which the null data is inserted in the fourth process are input to perform inverse fast Fourier transform, and a sixth process in which the signal subjected to inverse fast Fourier transform is transmitted. It is characterized by including.

  Yet another method of the present invention for achieving the above-described object is to divide all available frequency bands into a number of subcarrier bands, and to divide a number of subchannels that are a collection of one or more subcarrier bands. A transmission method of an OFDM (Frequency Hopping-Orthogonal Frequency Division Multiplexing) communication system comprising: a first process for fast Fourier transform of a received signal; and a fast Fourier transform in the first process. The transmitting apparatus separates the remaining subcarriers excluding the selected subcarrier from among the plurality of subcarriers and inserts null data so as to correspond to the remaining subcarriers. The second process, the third process for equalizing the signal generated in the second process, and the signal equalized in the frequency domain for high-speed frequency A fourth process for performing inverse fast Fourier transform so as to correspond to the matrix, a fifth process for equalizing the signal subjected to inverse fast Fourier transform in the time domain, and a fast process for performing fast Fourier transform on the signal equalized in the time domain. And 6th process and 7th process in which the signal corresponding to the remaining subcarriers is separated from the fast Fourier transformed signal in the 6th process and null data is inserted so as to correspond to the remaining subcarriers. And

  The present invention has the advantage of improving system performance by enabling fast frequency hopping and gaining frequency diversity gain even within one OFDM symbol time in an OFDM communication system. In addition, the present invention can apply a high-speed frequency hopping scheme not only to a frequency band but also to a part of a frequency band in an OFDM communication system, to apply a DCA scheme to an OFDM communication system, It has the advantage of improving the system performance by making it possible to apply a high-speed frequency hopping method for use.

  Hereinafter, detailed configurations and elements should be described so that an embodiment of the present invention can be understood. Accordingly, it is understood that those skilled in the art can make various changes and modifications without departing from the spirit and scope described in the present invention. Detailed descriptions of functions and structures well known in the following description are omitted.

  The present invention relates to a usable part of the entire frequency band used in a communication system using a fast frequency hopping (FFH) system and an OFDM system (hereinafter referred to as “FFH-OFDM communication system”). An apparatus and method for transmitting and receiving signals by performing high-speed frequency hopping using only a frequency band is proposed. Here, in the fast frequency hopping method, frequency hopping is performed at high speed by setting the frequency hopping period to an OFDM sample (sample) period that is not an OFDM symbol (symbol) period, or a period corresponding to a constant multiple of the OFDM sample. In the case of using the high-speed frequency hopping method, one OFDM symbol is spread over a number of sub-carriers in the frequency domain and is transmitted.

  First, a transmitter structure when performing high-speed frequency hopping using all frequency bands that can be used in the FFH-OFDM communication system will be described with reference to FIG.

  FIG. 1 is a block diagram illustrating a transmitter structure of an FFH-OFDM communication system that performs the functions of the first embodiment of the present invention.

  Referring to FIG. 1, the transmitter includes a serial to parallel converter 111, a high-speed frequency hopping device 120, a parallel to serial converter 131, a guard interval inserter. 133, a digital to analog converter 135, and a radio frequency (hereinafter referred to as 'RF') processor 137. The high-speed frequency hopping unit 120 includes an IFFT unit 121 and a linear processor 123.

と称することにし、並列信号

は下記の＜数式２＞のように表現される。 First, when input data to be transmitted is generated, the input data is input to the serial / parallel converter 111. Here, the data represents actual user data (user data) or reference data (pilot) or the like. The serial / parallel converter 111 converts the input data symbol into parallel and then outputs it to the IFFT unit 121. Here, the parallel signal output from the serial / parallel converter 111 is

Let's call the parallel signal

Is expressed as <Equation 2> below.

  In Equation 2, T represents a transpose operation, and Q represents the number of all usable subcarriers used in the FFH-OFDM communication system.

をＱ−ポイント（Q-point）ＩＦＦＴを遂行した後、線形処理機１２３に出力する。線形処理機１２３は、ＩＦＦＴ器１２１から出力した信号を入力して線形処理した後、並列／直列変換器１３１に出力する。 The IFFT device 121 outputs a signal output from the serial / parallel converter 111.

Is output to the linear processor 123 after performing Q-point IFFT. The linear processor 123 receives the signal output from the IFFT unit 121, performs linear processing, and then outputs it to the parallel / serial converter 131.

  Here, operations of the IFFT unit 121 and the linear processor 123 will be described.

とは相異する、下記の＜数式３＞のような新たな行列、即ち高速周波数ホッピング方式を適用して周波数変調を遂行するＱ×Ｑの大きさの行列（以下、‘高速周波数ホッピング行列’と称する）

に変更される。ここで、ＩＦＦＴ行列

は、従来技術部分で説明したようにＩＦＦＴ器の周波数変調動作に該当する行列である。 First, since all usable frequency bands are used in FIG. 1, high-speed frequency hopping is performed to hop subcarriers so that data is transmitted every OFDM sample time or every time corresponding to a multiple of OFDM sample time. The IFFT matrix described in the prior art part of the present invention.

Unlike the above, a new matrix such as the following <Formula 3>, that is, a matrix of Q × Q size that performs frequency modulation by applying a high-speed frequency hopping scheme (hereinafter, referred to as a “high-speed frequency hopping matrix”). Called)

Changed to Where IFFT matrix

Is a matrix corresponding to the frequency modulation operation of the IFFT device as described in the prior art section.

は、下記の＜数式４＞のように表現される。 In <Expression 3>, n represents a sample index (index), and m represents a sub-channel index. [Ф] _{n, m} represents a subcarrier on which data of the mth subchannel is transmitted in the nth sample, and therefore [ _した が っ_て ] _{n, m} determines a high-speed frequency hopping pattern when performing high-speed frequency hopping. . Further, in the present invention, a high-speed frequency hopping pattern that prevents subcarriers in which data is transmitted in arbitrary samples from overlapping is assumed, and a high-speed frequency hopping matrix is used for all high-speed frequency hopping patterns.

Is expressed as <Equation 4> below.

及び行列

のエレメント（element）値は、高速周波数ホッピングパターンによって予め決定された値で与えられる。ここで、行列

はその大きさがＱ×Ｑである。 In Equation 4, the fast frequency hopping matrix

And matrix

The element value is given by a value determined in advance by a fast frequency hopping pattern. Where the matrix

Has a size of Q × Q.

は常に対角（diagonal）行列で生成される。 Assuming that f _n of the high-speed frequency hopping pattern is a subcarrier on which the data of the first subchannel is transmitted in the n-th sample, the cyclic high-speed frequency hopping pattern defined as If used, the matrix of <Equation 4>

Is always generated in a diagonal matrix.

は一般的なＩＦＦＴ行列

に上記行列

を掛けた形態で得られて、したがって、高速周波数ホッピングを遂行する装置は、ＩＦＦＴ器と上記行列

を掛けてくれる線形処理機で具現可能になる。一方、本発明では、説明の便宜のため、循環高速周波数ホッピングパターンを一例として高速周波数ホッピングパターンを説明し、したがって上記行列

は対角行列で定義されるものであり、高速周波数ホッピングパターンの形態を変形可能であることは勿論である。 In this case, a fast frequency hopping matrix

Is a general IFFT matrix

To the above matrix

Therefore, an apparatus for performing fast frequency hopping is provided with an IFFT unit and the above matrix.

It can be realized with a linear processor that multiplies. On the other hand, in the present invention, for convenience of explanation, the high-speed frequency hopping pattern is described by taking the circular high-speed frequency hopping pattern as an example.

Is defined by a diagonal matrix, and of course, the form of the high-speed frequency hopping pattern can be modified.

と表現することにし、上記信号

は下記の＜数式６＞のように表すことができる。 On the other hand, the signal output from the linear processor 123 is

And the above signal

Can be expressed as <Formula 6> below.

を入力して直列変換した後、保護区間挿入器１３３に出力する。保護区間挿入器１３３は、並列／直列変換器１３１から出力した信号を入力して保護区間信号を挿入した後、デジタル／アナログ変換器１３５に出力する。ここで、保護区間は、ＦＦＨ−ＯＦＤＭ通信システムにおけるＯＦＤＭシンボルを送信する時、以前ＯＦＤＭシンボル時間に送信したＯＦＤＭシンボルと現在のＯＦＤＭシンボル時間に送信する現在のＯＦＤＭシンボルの間に干渉（interference）を除去するために挿入される。また、保護区間信号は、任意の時間領域のＯＦＤＭシンボルの最後の一定サンプルを複写して有効ＯＦＤＭシンボルに挿入する形態の‘Cyclic Prefix’方式や、または任意の時間領域のＯＦＤＭシンボルの最初の一定サンプルを複写して有効ＯＦＤＭシンボルに挿入する‘Cyclic Postfix’方式のうち、どれか一方式を使用して生成される。 The parallel / serial converter 131 outputs a signal output from the linear processor 123.

Is converted into a serial signal and then output to the guard interval inserter 133. The guard interval inserter 133 receives the signal output from the parallel / serial converter 131, inserts the guard interval signal, and then outputs the signal to the digital / analog converter 135. Here, when transmitting the OFDM symbol in the FFH-OFDM communication system, the guard interval causes interference between the OFDM symbol transmitted in the previous OFDM symbol time and the current OFDM symbol transmitted in the current OFDM symbol time. Inserted to remove. The guard interval signal is a 'Cyclic Prefix' method in which the last constant sample of an OFDM symbol in an arbitrary time domain is copied and inserted into an effective OFDM symbol, or the first constant of an OFDM symbol in an arbitrary time domain It is generated using one of the 'Cyclic Postfix' schemes that copy the sample and insert it into a valid OFDM symbol.

  The digital / analog converter 135 receives the signal output from the protection interval inserter 133 and performs analog conversion, and then outputs the signal to the RF processor 137. Here, the RF processor 137 includes components such as a filter and a front end unit, performs RF processing on the signal output from the digital / analog converter 135, and then transmits it to the actual channel. .

  FIG. 1 illustrates the transmitter structure of the FFH-OFDM communication system that performs the functions of the first embodiment of the present invention. Next, referring to FIG. 2, the functions of the first embodiment of the present invention are performed. The receiver structure of the FFH-OFDM communication system will be described.

  FIG. 2 is a block diagram illustrating a receiver structure of the FFH-OFDM communication system that performs the functions in the first embodiment of the present invention.

  Referring to FIG. 2, the receiver includes an RF processor 211, a digital / analog converter 213, a channel estimator 215, a guard interval remover 217, a serial / It comprises a parallel converter 219, an FFT unit 221, an equalizer 223, an IFFT unit 225, another equalizer 227, an FFT unit 229, and a parallel / serial converter 231.

と称することにし、上記雑音を

と称することにし、ｔは任意の時間領域（time domain）で測定されたものであることを表す。ＲＦ処理機２１１は、アンテナを介して受信された信号を中間周波数（ＩＦ：Intermediate Frequency）帯域へのダウンコンバーティング（down converting）、及び基底帯域へのダウンコンバーティングを遂行した後、デジタル／アナログ変換器２１３に出力する。デジタル／アナログ変換器２１３は、ＲＦ処理機２１１から出力したアナログ信号をデジタル変換した後、チャネル推定器２１５及び保護区間除去器２１７に出力する。 First, a signal transmitted from a transmitter of the FFH-OFDM communication system as described with reference to FIG. The noise is added to the RF processor 211 via the antenna. Where the channel matrix representing the channel response of the multipath channel is

The above noise

Let t denote that measured in an arbitrary time domain. The RF processor 211 performs digital signal / analog processing after down-converting a signal received through the antenna to an intermediate frequency (IF) band and down-converting to a base band. Output to the converter 213. The digital / analog converter 213 converts the analog signal output from the RF processor 211 into a digital signal, and then outputs the analog signal to the channel estimator 215 and the protection interval remover 217.

と称することにし、信号

は時間領域の信号であって、下記の＜数式７＞のように表すことができる。 The channel estimator 215 receives the signal output from the digital / analog converter 213, performs channel estimation, and outputs the result to the equalizer 223. Here, since the channel estimation operation of the channel estimator 215 is not directly related to the present invention, a detailed description thereof will be omitted. The protection interval remover 217 receives the signal output from the digital / analog converter 213, removes the protection interval signal, and then outputs the signal to the serial / parallel converter 219. The serial / parallel converter 219 receives the signal output from the protection interval remover 217, performs parallel conversion, and then outputs the signal to the FFT unit 221. Here, the signal output from the serial / parallel converter 219 is

Signal

Is a signal in the time domain, and can be expressed as <Formula 7> below.

をＱ−ポイントＦＦＴを遂行した後、等化器２２３に出力する。ここで、ＦＦＴ器２２１から出力する信号を

と称することにし、信号

は周波数領域の信号であって、下記の＜数式８＞のように表すことができる。 The FFT unit 221 outputs a signal output from the serial / parallel converter 219.

Is output to the equalizer 223 after performing Q-point FFT. Here, the signal output from the FFT unit 221 is

Signal

Is a signal in the frequency domain, and can be expressed as <Equation 8> below.

はＩＦＦＴ行列

のハーミシアン（Hermitian）を表す。 In <Formula 8>,

Is the IFFT matrix

Represents Hermitian.

  On the other hand, an equalization operation must be performed in order to compensate for signal distortion due to a multipath channel. In an FFH-OFDM communication system, an equalization operation must be performed in both the time domain and the frequency domain. Accordingly, the equalizer is a time domain equalizer that inputs a signal in the time domain to perform an equalization operation, and a frequency domain equalizer that performs an equalization operation by inputting a signal in the frequency domain. Requires one equalizer.

  Therefore, the equalizer 223 equalizes the signal output from the FFT unit 221 in the frequency domain, and then outputs the equalized signal to the IFFT unit 225. The equalizer 223 serves to compensate for the frequency domain channel response. Since the FFH-OFDM communication system uses a guard interval signal, the channel response in the time domain and the channel response in the frequency domain have a singular value decomposition (SVD) relationship, which is expressed by the following <Equation 9>. It can be expressed as

は周波数領域におけるチャネル応答を表すチャネル行列を表し、チャネル行列

は対角行列であるので、単一タップ（tap）等化器でも具現可能である。即ち、周波数領域の等化動作を遂行する等化器２２３は一般的なＯＦＤＭ通信システムの等化器と実質的に同一な動作を遂行し、チャネル補償方式によってＺＦ（Zero Forcing）等化器と、最小平均自乗エラー（ＭＭＳＥ：Minimum Mean Square Error）等化器と、マッチングフィルタ（matched filter）などを全て含む構造を有する。 In <Formula 9>,

Represents the channel matrix representing the channel response in the frequency domain, and the channel matrix

Since is a diagonal matrix, it can be implemented with a single tap equalizer. That is, the equalizer 223 that performs the frequency domain equalization operation performs substantially the same operation as an equalizer of a general OFDM communication system, and is a ZF (Zero Forcing) equalizer according to a channel compensation method. And a structure including all of a Minimum Mean Square Error (MMSE) equalizer, a matched filter, and the like.

  The IFFT unit 225 receives the signal output from the equalizer 223 and performs Q-point IFFT, and then outputs the signal to the equalizer 227. Here, the IFFT unit 225 performs the same operation as the IFFT unit 121 of the transmitter of FIG.

と定義することにし、時間領域における等化動作

は、下記の＜数式１０＞のように表すことができる。 The equalizer 227 receives the signal output from the IFFT unit 225, equalizes it in the time domain, and then outputs it to the FFT unit 229. Here, the equalization operation in the time domain is

Equalization operation in the time domain

Can be expressed as <Equation 10> below.

は＜数式４＞で表したような行列

のハーミシアン

で表現され、したがって、行列

は対角行列になる。 As shown in <Equation 10>, equalization operation in the time domain

Is a matrix as shown in <Formula 4>

The Hermitian

And thus the matrix

Becomes a diagonal matrix.

は下記の＜数式１１＞のように表すことができる。 The FFT unit 229 receives the signal output from the equalizer 227 and performs Q-point FFT, and then outputs it to the parallel / serial converter 231. Here, since the operation of the FFT unit 229 is substantially the same as the operation of the FFT unit 221, the detailed description thereof is omitted. Further, a signal output from the FFT unit 229, that is, an input data symbol estimation vector

Can be expressed as <Formula 11> below.

を遂行する場合、＜数式１１＞に表したような入力データシンボル推定ベクター

は下記の＜数式１２＞のように表すことができる。 As an example, the equalizer 223 uses a ZF equalizer that classifies the channel response for each subcarrier for the signal in the frequency domain as expressed in <Equation 8>, and the equalizer 227 expresses it in <Equation 10>. Equalization behavior

When performing the above, the input data symbol estimation vector as shown in <Formula 11>

Can be expressed as <Formula 12> below.

  The parallel / serial converter 231 performs serial conversion on the signal output from the FFT unit 229 and outputs the final input symbol.

  1 and 2, the FFH-OFDM communication system according to the first embodiment of the present invention, that is, performing fast frequency hopping using all available frequency bands, will be described. The FFH-OFDM communication system according to the second embodiment and the third embodiment, that is, performing fast frequency hopping using a usable partial frequency band will be described.

と仮定することにする。 First, the reason why high frequency hopping is performed using a partial frequency band in the second and third embodiments of the present invention corresponds to a specific subcarrier in an actual FFH-OFDM communication system. In order to use the frequency band to be used as a guard band, it does not transmit a signal in the frequency band corresponding to the guard band, or corresponds to a specific subcarrier among all the frequency bands usable for each user This is because a method for allocating a part of the frequency band to be transmitted and transmitting the signal is necessary. In particular, in the FFH-OFDM communication system, when using a dynamic channel allocation (hereinafter referred to as 'DCA') scheme that dynamically allocates subchannels to correspond to the user's channel state at each time point, System performance will be greatly improved. Therefore, the second and third embodiments of the present invention propose a method for performing high-speed frequency hopping using a part of the entire frequency band. In the following description of the second and third embodiments of the present invention, it is assumed that the total number of subcarriers used in the FFH-OFDM communication system is Q, and sub-bands corresponding to some frequency bands are used. The number of carriers

Let's assume that.

  The difference between the second embodiment and the third embodiment of the present invention will be briefly described as follows.

  First, the second embodiment of the present invention performs high-speed frequency hopping only on M subcarriers, and transmits the remaining subcarriers, that is, QM subcarriers with null data ( null data), for example, by inserting 0 and transmitting. In this case, if the frequency band corresponding to the M subcarriers is assumed to be the entire frequency band, it can be implemented by the same system as that described in the first embodiment of the present invention.

  Next, the third embodiment of the present invention performs fast frequency hopping on a total of Q subcarriers of M subcarriers and QM subcarriers to spread data, and then Null data is inserted into Q-M subcarriers excluding M subcarriers and transmitted. That is, in the third embodiment of the present invention, after null data is inserted into QM subcarriers in advance, fast frequency hopping is performed on Q subcarriers, and then QM subcarriers are added. Null data is inserted into the carrier and transmitted. In order for the third embodiment of the present invention to generate the same transmission signal as the second embodiment of the present invention, two conditions must be satisfied. Since the two conditions will be described later, detailed description thereof will be omitted here.

  Here, the transmitter structure of the FFH-OFDM communication system performing the functions in the second embodiment of the present invention will be described with reference to FIG.

  FIG. 3 is a block diagram illustrating a transmitter structure of an FFH-OFDM communication system that performs the functions of the second embodiment of the present invention.

  Referring to FIG. 3, the transmitter includes a serial / parallel converter 311, a high-speed frequency hopping unit 320, an FFT unit 331, a controller 333, an IFFT unit 335, a parallel / serial converter 337, a guard interval inserter 339, a digital / An analog converter 341 and an RF processor 343 are included. The high-speed frequency hopping unit 320 includes an IFFT unit 321 and a linear processor 323.

と称することにし、並列信号

は下記の＜数式１３＞のように表現される。 First, when input data to be transmitted is generated, the input data is input to the serial / parallel converter 311. Here, the data represents actual user data or reference data such as a pilot, and the second embodiment of the present invention proposes a case where fast frequency hopping is performed only on M subcarriers. Therefore, the serial / parallel converter 311 converts the input data symbols into M symbols in parallel, and then outputs them to the IFFT unit 321. Here, the parallel signal output from the serial / parallel converter 311 is

Let's call the parallel signal

Is expressed as <Equation 13> below.

をＭ−ポイントＩＦＦＴを遂行した後、線形処理機３２３に出力する。線形処理機３２３は、ＩＦＦＴ器３２１から出力した信号を入力して線形処理した後、ＦＦＴ器３３１に出力する。 The IFFT unit 321 is a parallel signal output from the serial / parallel converter 311.

Is output to the linear processor 323 after performing M-point IFFT. The linear processor 323 receives the signal output from the IFFT unit 321, performs linear processing, and then outputs the signal to the FFT unit 331.

  Here, operations of the IFFT unit 321 and the linear processor 323 will be described.

と同一な方式により生成される。しかしながら、本発明の第２実施形態では、その行列の大きさが本発明の第１実施形態における

とは相異する高速周波数ホッピング行列

に変更され、高速周波数ホッピング行列

は、下記の＜数式１４＞のように表現される。 First, in FIG. 3, only M subcarriers are used instead of all available frequency bands. Therefore, when performing fast frequency hopping on subcarriers to transmit data every OFDM sample time or every time corresponding to a multiple of OFDM sample time, the fast frequency hopping matrix described in the first embodiment of the present invention.

It is generated by the same method. However, in the second embodiment of the present invention, the size of the matrix is the same as in the first embodiment of the present invention.

Different from the fast frequency hopping matrix

Changed to a fast frequency hopping matrix

Is expressed as <Formula 14> below.

はその大きさがＭ×Ｍである。また、本発明では任意のサンプルからデータが送信されるサブキャリヤが重複しないようにする高速周波数ホッピングパターンを仮定し、全ての高速周波数ホッピングパターンに対して高速周波数ホッピング行列

を下記の＜数式１５＞のように表現することができる。 In Equation 14, the fast frequency hopping matrix

Has a size of M × M. Further, in the present invention, a high-speed frequency hopping pattern that prevents subcarriers in which data is transmitted from arbitrary samples from overlapping is assumed, and a high-speed frequency hopping matrix is used for all high-speed frequency hopping patterns.

Can be expressed as <Formula 15> below.

及び行列

のエレメント値は、高速周波数ホッピングパターンによって予め決定された値で与えられる。 In Equation 15, the fast frequency hopping matrix

And matrix

The element value is given as a value determined in advance by a high-speed frequency hopping pattern.

は常に対角行列で生成される。 When it is assumed that f _n of the fast frequency hopping pattern is a subcarrier in which the data of the first subchannel is transmitted in the nth sample, a cyclic fast frequency hopping pattern defined as in the following <Formula 16> is used. , <Formula 15> matrix

Is always generated as a diagonal matrix.

は一般的なＩＦＦＴ行列

に行列

を掛けた形態で表現され、したがって、高速周波数ホッピングを遂行する装置は、ＩＦＦＴ器と行列

を掛けてくれる線形処理機で具現可能になる。一方、本発明では、説明の便宜のため、循環高速周波数ホッピングパターンを一例として高速周波数ホッピングパターンを説明し、したがって、行列

は対角行列と定義されるものであり、高速周波数ホッピングパターンの形態を変形可能であることは勿論である。 In this case, a fast frequency hopping matrix

Is a general IFFT matrix

Matrix

Therefore, an apparatus that performs fast frequency hopping is an IFFT unit and a matrix.

It can be realized with a linear processor that multiplies. On the other hand, in the present invention, for convenience of explanation, the high-speed frequency hopping pattern is described by taking the circular high-speed frequency hopping pattern as an example.

Is defined as a diagonal matrix, and of course, the form of the high-speed frequency hopping pattern can be modified.

と表現することにし、信号

は下記の＜数式１７＞のように表すことができる。 On the other hand, the signal output from the linear processor 323 is

And the signal

Can be expressed as <Equation 17> below.

を入力してＭ−ポイントＦＦＴを遂行した後、制御器３３３に出力する。制御器３３３は、ＦＦＴ器３３１から出力した信号を入力し、Ｍ個のサブキャリヤ帯域の以外のＱ−Ｍ個のサブキャリヤ帯域にナルデータ、一例として０を挿入した後、ＩＦＦＴ器３３５に出力する。ここで、制御器３３３は一種の０挿入器（０inserter）として動作するものであり、制御器３３３の０挿入動作は下記の＜数式１８＞のように表すことができる。 The FFT unit 331 outputs a signal output from the linear processor 323.

Is input to the controller 333 after performing M-point FFT. The controller 333 receives the signal output from the FFT unit 331, inserts null data, for example, 0 into the QM subcarrier bands other than the M subcarrier bands, and then outputs it to the IFFT unit 335. To do. Here, the controller 333 operates as a kind of 0 inserter, and the 0 insertion operation of the controller 333 can be expressed as the following <Equation 18>.

は，図３の制御器３３３の動作を表す行列であり、前述したように、制御器３３３の出力信号の中で、Ｍ個のサブキャリヤを通じて送信されるデータに対しては既に高速周波数ホッピングが遂行されたものであり、Ｑ−Ｍ個のサブキャリヤを通じて送信されるナルデータに対しては全く高速周波数ホッピングになっていない状態である。 the above

Is a matrix representing the operation of the controller 333 of FIG. 3, and as described above, high-speed frequency hopping is already applied to data transmitted through M subcarriers in the output signal of the controller 333. The null data transmitted through Q-M subcarriers has not been subjected to high-speed frequency hopping.

と称することにし、信号

は，下記の＜数式１９＞のように表すことができる。 The IFFT unit 335 receives the signal output from the controller 333 and performs Q-point IFFT, and then outputs the signal to the parallel / serial converter 337. Here, the signal output from the IFFT unit 335 is

Signal

Can be expressed as <Equation 19> below.

  The parallel / serial converter 337, the protection interval inserter 339, the digital / analog converter 341, and the RF processor 343 include the parallel / serial converter 131, the protection interval inserter 133, the digital / analog converter 135 of FIG. Since the same operation as that of the RF processor 137 is performed, detailed description thereof is omitted here.

  In FIG. 3, the transmitter structure of the FFH-OFDM communication system performing the functions in the second embodiment of the present invention has been described. Next, referring to FIG. 4, the functions of the second embodiment of the present invention are performed. A receiver structure of the FFH-OFDM communication system will be described.

  FIG. 4 is a block diagram illustrating a receiver structure of an FFH-OFDM communication system that performs the functions of the second embodiment of the present invention.

  Referring to FIG. 4, the receiver includes an RF processor 411, an analog / digital converter 413, a channel estimator 415, a guard interval remover 417, a serial / parallel converter 419, an FFT unit 421, a controller 423, equalization. 425, IFFT unit 427, equalizer 429, FFT unit 431, and parallel / serial converter 433. In FIG. 4, the RF processor 411, the analog / digital converter 413, the protection interval remover 417, and the serial / parallel converter 419 are the RF processor 211, the digital / analog converter 213, and the protection interval described in FIG. Since the same operation as that of the remover 217 and the serial / parallel converter 219 is performed, detailed description thereof will be omitted.

と称することにし、信号

は時間領域の信号であって、下記の＜数式２０＞のように表すことができる。 The signal output from the serial / parallel converter 419

Signal

Is a signal in the time domain, and can be expressed as <Equation 20> below.

をＱ−ポイントＦＦＴを遂行した後、制御器４２３に出力する。ここで、ＦＦＴ器４２１で出力する信号を

と称することにし、信号

は周波数領域の信号であって、下記の＜数式２１＞のように表すことができる。 The FFT unit 421 is a signal output from the serial / parallel converter 419.

Is output to the controller 423 after performing Q-point FFT. Here, the signal output from the FFT unit 421 is

Signal

Is a signal in the frequency domain and can be expressed as <Formula 21> below.

でナルデータ、一例として０が含まれているＱ−Ｍ個のサブキャリヤ信号を除去し、Ｍ個のサブキャリヤのみを等化器４２５に出力する。ここで、制御器４２３は一種の０除去器（０remover）として動作するものであり、制御器４２３の動作は、図３の制御器３３３で挿入した０を除去するものである。 On the other hand, of the Q subcarrier signals output from the FFT unit 421, the data is included only in the M subcarrier signals, so the controller 423 outputs the data from the FFT unit 421.

The QM subcarrier signals containing null data, for example, 0 are removed, and only M subcarriers are output to the equalizer 425. Here, the controller 423 operates as a kind of zero remover (0 remover), and the operation of the controller 423 removes the zero inserted by the controller 333 in FIG.

  The operation of the controller 423 can be expressed as the following <Equation 22>.

  On the other hand, an equalization operation must be performed in order to compensate for signal distortion due to a multipath channel. In an FFH-OFDM communication system, an equalization operation must be performed in both the time domain and the frequency domain. Accordingly, the equalizer is a time domain equalizer that inputs a signal in the time domain to perform an equalization operation, and a frequency domain equalizer that performs an equalization operation by inputting a signal in the frequency domain. Requires one equalizer.

  Therefore, the equalizer 425 equalizes the signal output from the controller 423 in the frequency domain, and then outputs it to the IFFT unit 427. The equalizer 425 serves to compensate for the frequency domain channel response.

  The IFFT unit 427 receives the signal output from the equalizer 425, performs M-point IFFT, and then outputs the signal to the equalizer 429. Here, the IFFT unit 427 performs the same operation as the IFFT unit 321 of the transmitter of FIG.

と定義することにし、時間領域における等化動作

は、下記の＜数式２３＞のように表すことができる。 The equalizer 429 receives the signal output from the IFFT unit 427 and equalizes it in the time domain, and then outputs it to the FFT unit 431. Here, the equalization operation in the time domain is

Equalization operation in the time domain

Can be expressed as <Formula 23> below.

は、＜数式１５＞で表したような行列

のハーミシアン

で表現され、したがって、行列

は対角行列になる。 As shown in <Equation 23>, equalization operation in the time domain

Is a matrix as shown in <Formula 15>

The Hermitian

And thus the matrix

Becomes a diagonal matrix.

は、下記の＜数式２４＞のように表すことができる。一方、下記の＜数式２４＞において、

は、ＦＦＴ器４３１から出力されて制御器４２３に入力される信号であって、

、

、

、

、

の各々は順次にＦＦＴ器４３１、等化器４２９、ＩＦＦＴ器４２７、等化器４２５、及び制御器４２３を表す行列である。 The FFT unit 431 receives the signal output from the equalizer 429 and performs M-point FFT, and then outputs it to the parallel / serial converter 433. Here, the operation of the FFT unit 431 is substantially the same as the operation of the FFT unit 331 of FIG. Further, a signal output from the FFT unit 431, that is, an input data symbol estimation vector

Can be expressed as <Equation 24> below. On the other hand, in the following <Equation 24>

Is a signal output from the FFT unit 431 and input to the controller 423,

,

,

,

,

Are matrices representing the FFT unit 431, the equalizer 429, the IFFT unit 427, the equalizer 425, and the controller 423 in sequence.

  The parallel / serial converter 433 performs serial conversion on the signal output from the FFT unit 431 and outputs the final input symbol.

  In FIG. 4, the receiver structure of the FFH-OFDM communication system performing the functions in the second embodiment of the present invention has been described. Next, referring to FIG. 5, the functions of the third embodiment of the present invention are performed. A transmitter structure of the FFH-OFDM communication system will be described.

  FIG. 5 is a block diagram illustrating a transmitter structure of an FFH-OFDM communication system performing functions in the third embodiment of the present invention.

  Referring to FIG. 5, the transmitter includes a serial / parallel converter 511, a controller 513, a high-speed frequency hopping unit 520, an FFT unit 531, a controller 533, an IFFT unit 535, a parallel / serial converter 537, and a guard interval inserter. 539, a digital / analog converter 541, and an RF processor 543. The high-speed frequency hopping unit 520 includes an IFFT unit 521 and a linear processor 523.

  First, when input data to be transmitted is generated, the input data is input to the serial / parallel converter 511. Here, the data represents actual user data or a reference signal such as a pilot, and the third embodiment of the present invention proposes a case where high-speed frequency hopping is performed only on M subcarriers. Therefore, the serial / parallel converter 511 converts the input data symbols into M symbols in parallel, and then outputs them to the controller 513. The controller 513 receives the signal output from the serial / parallel converter 511 and inserts null data, for example, 0 into QM subcarrier bands other than the M subcarrier bands, and then an IFFT unit. It outputs to 521. Here, the controller 513 operates as a kind of zero inserter.

  The IFFT unit 521 receives the signal output from the controller 513 and performs Q-point IFFT, and then outputs the signal to the linear processor 523. The linear processor 523 receives the signal output from the IFFT unit 521, performs linear processing, and then outputs it to the FFT unit 531. Here, the operations of the IFFT unit 521 and the linear processor 523 are the same as the operations of the IFFT unit 121 and the linear processor 123 of FIG.

と称することにし、信号

はデータが含まれたＭ個のサブキャリヤ信号とナルデータが含まれたＱ−Ｍ個のサブキャリヤ信号が時間領域で広がった信号である。 The FFT unit 531 receives the signal output from the FFH unit 520 and performs Q-point FFT, and then outputs the signal to the controller 533. Here, the signal output from the FFT unit 531 is

Signal

Is a signal in which M subcarrier signals including data and QM subcarrier signals including null data are spread in the time domain.

を入力してＱ−Ｍ個のサブキャリヤに対応するように０を挿入した後、ＩＦＦＴ器５３５に出力する。ここで、制御器５３３は一種の０挿入器として動作するものであり、制御器５３３の０挿入動作は、下記の＜数式２５＞のように表すことができる。 The controller 533 outputs the signal output from the FFT unit 531.

And 0 is inserted so as to correspond to Q−M subcarriers, and then output to IFFT unit 535. Here, the controller 533 operates as a kind of 0-inserter, and the 0-insertion operation of the controller 533 can be expressed as the following <Equation 25>.

ＩＦＦＴ器５３５は、制御器５３３から出力した信号を入力してＱ−ポイントＩＦＦＴを遂行した後、並列／直列変換器５３７に出力する。ここで、ＩＦＦＴ器５３５から出力する信号を

と称することにし、信号

は下記の＜数式２６＞のように表すことができる。一方、下記の＜数式２６＞において、

は、制御器５１３に入力されるデータベクターを表し、

、

、

、

、

、

の各々は、順次に制御器５１３、ＩＦＦＴ器５２１、線形処理機５２３、ＦＦＴ器５３１、制御器５３３、及びＩＦＦＴ器５３５を表す行列である。

The IFFT unit 535 receives the signal output from the controller 533 and performs Q-point IFFT, and then outputs the signal to the parallel / serial converter 537. Here, the signal output from the IFFT unit 535 is

Signal

Can be expressed as <Equation 26> below. On the other hand, in the following <Equation 26>

Represents a data vector input to the controller 513,

,

,

,

,

,

Are matrices representing the controller 513, the IFFT unit 521, the linear processor 523, the FFT unit 531, the controller 533, and the IFFT unit 535 in sequence.

  As shown in <Equation 26>, after adding M subcarrier signals to which data is transmitted and QM subcarrier signals to which null data is transmitted to generate a signal of magnitude Q, When performing high-speed frequency hopping, the number of subcarriers used in each configuration of the transmitter is fixed to Q. Therefore, regardless of the number M of subcarriers to which actual data is transmitted, hardware-like Therefore, it has an advantage that a stable transmitter configuration is possible.

と＜数式２６＞に表したような送信ベクター

は、次のような２つの条件を満たさなければならない。 On the other hand, a transmission vector as expressed in <Equation 19>

And the transmission vector as shown in <Equation 26>

Must satisfy the following two conditions.

と送信ベクター

を同一な形態にするために、

のエレメントの値を基盤にして

のエレメントの値を設定しなければならない。上記の第１条件は、＜数式２７＞のように表すことができる。 (1) First condition transmission vector

And send vector

To have the same form

Based on the value of the element

The value of the element must be set. The first condition can be expressed as <Equation 27>.

が掛けられるものである。 As described above, in the third embodiment of the present invention, the signal transmitted through the QM subcarriers is replaced with null data, so that it has the same overall energy as the second embodiment of the present invention. In order to do this,

Is to be multiplied.

(2) Second Condition The second condition is a condition for ensuring that the transmission vectors transmitted in the second embodiment and the third embodiment of the present invention always have the same value. 28>.

  The parallel / serial converter 537, the protection interval inserter 539, the digital / analog converter 541, and the RF processor 543 are the parallel / serial converter 131, the protection interval inserter 133, the digital / analog converter 135 of FIG. Since the same operation as that of the RF processor 137 is performed, detailed description thereof is omitted here.

  In FIG. 5, the transmitter structure of the FFH-OFDM communication system performing the functions in the third embodiment of the present invention has been described, and then the functions in the third embodiment of the present invention are performed with reference to FIG. 6. A transmitter structure of the FFH-OFDM communication system will be described.

  FIG. 6 is a block diagram illustrating a receiver structure of an FFH-OFDM communication system that performs the functions of the third embodiment of the present invention.

  Referring to FIG. 6, the receiver includes an RF processor 611, an analog / digital converter 613, a channel estimator 615, a guard interval remover 617, a serial / parallel converter 619, an FFT unit 621, a controller 623, and an equalization. 625, IFFT unit 627, equalizer 629, FFT unit 631, controller 633, and parallel / serial converter 635. In FIG. 6, the RF processor 611, the analog / digital converter 613, the protection interval remover 617, and the serial / parallel converter 619 are the RF processor 211, the digital / analog converter 213, and the protection interval described in FIG. Since the same operation as that of the remover 217 and the serial / parallel converter 219 is performed, detailed description thereof will be omitted. The FFT unit 621 performs the same operation as the FFT unit 421 described with reference to FIG. 4, and thus detailed description thereof is omitted here.

と，ＦＦＴ器６２１から出力する信号

は、＜数式２０＞及び＜数式２１＞で説明した

と

と同一な信号である。そして、図５で説明した送信機において、実際のデータを送信するサブキャリヤの個数はＭ個であるので、周波数領域の信号

はＭ個のサブキャリヤ信号にはデータが、残りのＱ−Ｍ個のサブキャリヤ信号には雑音のみ含まれている。したがって、制御器６２３は、ＦＦＴ器６２１から出力した信号

からＱ−Ｍ個のサブキャリヤに該当する信号を除去し、ナルデータ、一例として０を挿入した後、等化器６２５に出力する。ここで、制御器６２３は一種の０挿入器として機能するものである。 On the other hand, the signal input to the FFT unit 621

And the signal output from the FFT unit 621

Are described in <Equation 20> and <Equation 21>.

When

Is the same signal. In the transmitter described with reference to FIG. 5, since the number of subcarriers that transmit actual data is M, the frequency domain signal

The M subcarrier signals contain data, and the remaining QM subcarrier signals contain only noise. Therefore, the controller 623 outputs the signal output from the FFT unit 621.

Then, signals corresponding to QM subcarriers are removed, null data, for example, 0 is inserted, and output to the equalizer 625. Here, the controller 623 functions as a kind of zero inserter.

のハーミシアンと定義され、これは下記の＜数式２９＞のように表現される。 The equalizer 625 receives the signal output from the controller 623, equalizes it in the frequency domain, and outputs it to the IFFT unit 627. The IFFT unit 627 receives the signal output from the equalizer 625 and performs Q-point IFFT, and then outputs the signal to the equalizer 629. The equalizer 629 receives the signal output from the IFFT unit 627, equalizes it in the time domain, and then outputs it to the FFT unit 631. Here, the equalizer 629 is a matrix of the linear processor 623 of the transmitter of FIG.

This is expressed as <Equation 29> below.

  The FFT unit 631 receives the signal output from the equalizer 629 and performs Q-point FFT, and then outputs the signal to the controller 633. Since the signal output from the FFT unit 631 also has M subcarriers for transmitting actual data, the controller 633 selects only signals corresponding to M estimated data as shown in <Equation 30> below. Output. Here, the controller 633 operates as a kind of selector.

The parallel / serial converter 635 serially converts the signal output from the FFT unit 633 and outputs the signal including the final input symbol.
As described above, since the transmission vectors transmitted by the transmitters of the second embodiment and the third embodiment of the present invention are the same, the third embodiment of the present invention corresponds to the transmitter of the second embodiment of the present invention. The receiver of the embodiment can also be used, and the receiver of the second embodiment of the present invention can be used corresponding to the transmitter of the third embodiment of the present invention.

  On the other hand, in the second and third embodiments of the present invention, the operation for performing high-speed frequency hopping has been described on the assumption that data targeting only one user is transmitted. When the entire frequency band is divided and allocated to a large number of users in the downlink channel, a part of each of the large numbers of users is as in the second and third embodiments of the present invention. A transmitter and receiver that perform high-speed frequency hopping using a frequency band are required. The fourth embodiment of the present invention proposes a method for performing high-speed frequency hopping considering a large number of users, ie, considering multiple connections.

  Here, with reference to FIG. 7, an OFDMA communication system that performs high-speed frequency hopping in consideration of a large number of users (hereinafter referred to as a “high-speed frequency hopping OFDMA communication system”) will be described.

  FIG. 7 is a block diagram illustrating a transmitter structure of a fast frequency hopping OFDMA communication system performing functions in the fourth embodiment of the present invention.

  Referring to FIG. 7, the transmitter includes a high-speed frequency hopping / OFDM processing unit 710, a multiplexer 720, an IFFT unit 730, a parallel / serial converter 740, a guard interval inserter 750, and a digital / analog converter 760. , And an RF processor 770. The high-speed frequency hopping / OFDM processing unit 710 includes a plurality of high-speed frequency hopping / OFDM processors, that is, first high-speed frequency hopping / OFDM processors 711-1 to 711-1 that process data targeted for the first user. It consists of a Kth fast frequency hopping / OFDM processor 711-K that processes data targeting K users. As an example, the second fast frequency hopping / OFDM processor 111-2 processes only data targeted to the second user.

乃至

と仮定する。データ

は第１の高速周波数ホッピング／ＯＦＤＭ処理機７１１−１に、このように、データ

は第Ｋの高速周波数ホッピング／ＯＦＤＭ処理機７１１−Ｋに入力される。 First, the number of subcarriers assigned to a user of the first user, second K to be assumed that M ₁ to M _K, the data to be transmitted to the user of the first user, second K

Thru

Assume that data

To the first fast frequency hopping / OFDM processor 711-1 in this way, the data

Is input to the Kth fast frequency hopping / OFDM processor 711-K.

乃至

を出力する。一例として、第Ｋの高速周波数ホッピング／ＯＦＤＭ処理機７１１−Ｋが本発明の第２実施形態のような方式により高速周波数ホッピング及びＯＦＤＭ変調を遂行する場合、図３の制御器３３３から出力する信号の中、実際に使用するサブキャリヤの個数であるＭ_Ｋ個のエレメントが

になるものであり、これとは異なり、第Ｋの高速周波数ホッピング／ＯＦＤＭ処理機７１１−Ｋが本発明の第３実施形態のような方式により高速周波数ホッピング及びＯＦＤＭ変調を遂行する場合、図５の制御器５３３から出力する信号のうち、実際に使用するサブキャリヤの個数であるＭ_Ｋ個のエレメントが

になるものである。 The first high-speed frequency hopping / OFDM processor 711-1 to the K-th high-speed frequency hopping / OFDM processor 711-K are high-speed by the method described in the second embodiment or the third embodiment of the present invention. After performing frequency hopping and OFDM modulation, the modulated signal

Thru

Is output. As an example, when the K-th fast frequency hopping / OFDM processor 711-K performs high-speed frequency hopping and OFDM modulation according to the method of the second embodiment of the present invention, a signal output from the controller 333 of FIG. M _K elements which are the number of subcarriers actually used are

In contrast, when the K-th fast frequency hopping / OFDM processor 711-K performs high-speed frequency hopping and OFDM modulation according to the method of the third embodiment of the present invention, FIG. Among the signals output from the controller 533, there are M _K elements which are the number of subcarriers actually used.

It will be.

乃至

は多重化器７２０に入力され、多重化器７２０はどのユーザにも割り当てられていない

に該当するサブキャリヤ信号に０を挿入した後、ＩＦＦＴ器７３０に出力する。ＩＦＦＴ器７３０は、多重化器７２０から出力した信号を入力してＱ−ポイントＩＦＦＴを遂行した後、並列／直列変換器７４０に出力する。並列／直列変換器７４０、保護区間挿入器７５０、デジタル／アナログ変換器７６０、及びＲＦ処理機７７０は、図１の並列／直列変換器１３１、保護区間挿入器１３３、デジタル／アナログ変換器１３５、及びＲＦ処理機１３７と同一な動作を遂行するので、ここではその詳細な説明を省略する。また、図７は送信機で多数のユーザのための信号を共に多重化（multiplexing）して伝送する一方、受信機ではこれと関わらず、常に自己信号のみ復調するので、別途の具現を必要としないで、本発明の第２実施形態または第３実施形態で説明した受信機を使用することができる。 Signals output from the first high-speed frequency hopping / OFDM processor 711-1 to the K-th high-speed frequency hopping / OFDM processor 711-K

Thru

Is input to multiplexer 720, which is not assigned to any user

0 is inserted into the subcarrier signal corresponding to, and then output to IFFT unit 730. The IFFT unit 730 receives the signal output from the multiplexer 720 and performs Q-point IFFT, and then outputs the signal to the parallel / serial converter 740. The parallel / serial converter 740, the protection interval inserter 750, the digital / analog converter 760, and the RF processor 770 include the parallel / serial converter 131, the protection interval inserter 133, the digital / analog converter 135 of FIG. Since the same operation as that of the RF processor 137 is performed, detailed description thereof is omitted here. In addition, FIG. 7 multiplexes and transmits signals for a large number of users together at the transmitter, but the receiver always demodulates only the self signal, so that separate implementation is required. Instead, the receiver described in the second embodiment or the third embodiment of the present invention can be used.

  In the detailed description of the present invention, specific embodiments have been described. However, it goes without saying that various modifications can be made without departing from the scope of the present invention by those skilled in the art. is there. Therefore, the scope of the present invention should be determined by the claims.

FIG. 2 is a block diagram illustrating a transmitter structure of a high-speed frequency hopping-OFDM communication system performing functions in the first embodiment of the present invention. FIG. 2 is a block diagram illustrating a receiver structure of a high-speed frequency hopping-OFDM communication system performing functions in the first embodiment of the present invention. FIG. 6 is a block diagram illustrating a transmitter structure of a high-speed frequency hopping-OFDM communication system performing functions in a second embodiment of the present invention. FIG. 6 is a block diagram illustrating a receiver structure of a high-speed frequency hopping-OFDM communication system performing functions in a second embodiment of the present invention. FIG. 6 is a block diagram illustrating a transmitter structure of a high-speed frequency hopping-OFDM communication system performing functions in a third embodiment of the present invention. FIG. 6 is a block diagram illustrating a receiver structure of a high-speed frequency hopping-OFDM communication system performing functions in a third embodiment of the present invention. FIG. 7 is a block diagram illustrating a transmitter structure of a high-speed frequency hopping-OFDMA communication system performing functions in a fourth embodiment of the present invention.

Explanation of symbols

111 serial / parallel converter 120 high-speed frequency hopping device 121 IFFT device 123 linear processor 131 parallel / serial converter 133 guard interval inserter 135 digital / analog converter 137 radio frequency processor

Claims (48)

Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels composed of one or more subcarrier bands, dividing all usable frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) signal transmission device of communication system,
A fast frequency hopper that assigns input data to a number of subcarriers selected from all available subcarriers and performs fast frequency hopping with a fast frequency hopping signal generated by a fast frequency hopping pattern;
A fast Fourier transformer for fast Fourier transforming a high-speed frequency hopping signal;
A controller for inserting null data into the remaining subcarriers after the selection;
A first inverse fast Fourier transformer configured to perform an inverse fast Fourier transform on the selected subcarrier configured with the input data and the remaining subcarriers to which the null data is input;
A transmitter for transmitting the first inverse fast Fourier transform signal. The high-speed frequency hopper is
A second inverse fast Fourier transformer that assigns input data to the selected subcarrier and performs an inverse fast Fourier transform of the selected subcarrier;
And a linear processor for performing linear processing so that the selected subcarrier has a predetermined gain, which has been inverse fast Fourier transformed by the second inverse fast Fourier transformer. The device described. The high-speed frequency hopping device is a high-speed frequency hopping matrix as shown in the following <Equation 31>.

3. The apparatus of claim 2, wherein fast frequency hopping is performed so as to correspond to

In <Expression 31>, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n and m} are data of the m-th sub-channel in the n-th sample. M represents a number of partial subcarriers selected from all Q usable subcarriers used in the FFH-OFDM communication system. The second inverse fast Fourier transform is an inverse fast Fourier transform matrix of an M-point inverse fast Fourier transform device of the following <Equation 32>.

4. The apparatus according to claim 3, wherein an inverse fast Fourier transform is performed on the subcarrier signals corresponding to the M subcarriers in a one-to-one correspondence with the M subcarriers.

The linear processor is
When the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the subcarrier signal subjected to inverse fast Fourier transform by the second inverse fast Fourier transformer is multiplied by a preset diagonal matrix and linearly processed. An apparatus according to claim 4. The linear processor is a matrix such as the following <Equation 33>.

6. The apparatus according to claim 5, wherein the subcarrier signal subjected to the inverse fast Fourier transform by the second inverse fast Fourier transformer is linearly processed so as to correspond to.

In <Formula 33>,

Is the inverse fast Fourier transform matrix

Represents Hermitian. The apparatus according to claim 6, wherein the cyclic high-speed frequency hopping pattern is a high-speed frequency hopping pattern defined as in the following <Equation 34>.

Wherein the <Equation 34>, f _n of the fast frequency hopping pattern represents the sub-carrier data of the first sub-channel is transmitted by the n-th sample. Fast frequency hopping-Orthogonal Frequency Division Multiplexing (OFDM) comprising multiple subchannels that are a collection of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands Division Multiplexing) communication system signal transmission method,
Assigning input data to a number of subcarriers selected from all the available subcarriers and performing fast frequency hopping with a fast frequency hopping signal generated by a fast frequency hopping pattern;
A process of fast Fourier transforming a fast frequency hopping signal;
Inserting null data into the remaining subcarriers after the selection;
Performing an inverse fast Fourier transform to generate a first inverse fast Fourier transform signal from the selected subcarrier configured with the input data and the remaining subcarriers to which the null data is input; ,
Transmitting the first inverse fast Fourier transform signal. The process of performing the fast frequency hopping includes:
A first step of assigning input data to the selected subcarrier and performing an inverse fast Fourier transform of the selected subcarrier;
9. A second process of performing linear processing so that the selected subcarrier has a predetermined gain, which is inverse fast Fourier transformed by the second inverse fast Fourier transformer. The method described. The fast frequency hopping process is performed by a fast frequency hopping matrix as shown in the following formula 35

10. The method of claim 9, wherein the method is performed to correspond to:

In <Formula 35>, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n and m} are n-th samples and data of the m-th sub-channel is transmitted. M represents the number of subcarriers selected from among all Q usable subcarriers used in the FFH-OFDM communication system. The first process includes an M-point inverse fast Fourier transform matrix of the following <Equation 36>

11. The method according to claim 10, wherein a sub-carrier signal corresponding to the M sub-carriers corresponding to the M sub-carriers is subjected to an inverse fast Fourier transform.

  In the second process, when the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the subcarrier signal subjected to inverse fast Fourier transform by the second inverse fast Fourier transformer is linearly multiplied by a preset diagonal matrix. The method according to claim 11, wherein the processing is performed. 13. The method according to claim 12, wherein the cyclic fast frequency hopping pattern is a fast frequency hopping pattern defined as in the following <Equation 37>.

In Equation 37, f _n of the high-speed frequency hopping pattern represents a subcarrier on which data of the first subchannel is transmitted in the nth sample. Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels that are a set of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) signal transmission device of communication system,
A first Fast Fourier Transform that fast Fourier transforms the received signal;
The transmitter separates the remaining subcarriers excluding the subcarriers selected from among the plurality of subcarriers from the signal subjected to the fast Fourier transform in the first fast Fourier transformer, and the remaining subcarriers. A controller for inserting null data so as to correspond to
A first equalizer for equalizing the output signal of the controller in the frequency domain;
An inverse fast Fourier transformer that performs an inverse fast Fourier transform on the signal equalized by the first equalizer so as to correspond to the fast frequency hopping matrix applied by the transmission device;
A second equalizer for equalizing the inverse fast Fourier transformed signal in the time domain;
And a second fast Fourier transformer that performs a fast Fourier transform on the signal equalized in the time domain. 15. The apparatus according to claim 14, wherein the fast frequency hopping matrix is expressed as in the following <Equation 38>.

In <Formula 38>,

Represents the fast frequency hopping matrix, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n, m} are the nth sample and the data of the mth subchannel is A subcarrier to be transmitted is represented, and M represents the number of subcarriers selected from all Q subcarriers that can be used in the FFH-OFDM communication system.   The second equalizer, when the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, performs equalization by multiplying the inverse fast Fourier transformed subcarrier signal by a preset diagonal matrix Hermitian. The apparatus of claim 15. The apparatus according to claim 16, wherein the cyclic high-speed frequency hopping pattern is a high-speed frequency hopping pattern defined as in the following <Equation 39>.

In Equation 39, f _n of the high-speed frequency hopping pattern represents a subcarrier on which data of the first subchannel is transmitted in the nth sample. Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels that are a set of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) communication system signal transmission method,
A first process for fast Fourier transform of the received signal;
The transmission apparatus transmits data to the remaining subcarriers excluding the selected subcarrier among the plurality of subcarriers using the signal subjected to the fast Fourier transform by the first fast Fourier transformer in the first process. A second step of separating the corresponding signals and inserting null data into the remaining subcarriers;
A third step of equalizing the signal generated in the second step in the frequency domain;
A fourth step of performing an inverse fast Fourier transform on the signal equalized in the frequency domain by the fast frequency hopping matrix;
A fifth step of equalizing the inverse fast Fourier transformed signal in the time domain;
And a sixth step of performing a fast Fourier transform on the signal equalized in the time domain. 19. The method of claim 18, wherein the fast frequency hopping matrix is expressed as in the following <Equation 40>.

In <Formula 40>,

Represents the fast frequency hopping matrix, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n, m} are the nth sample and the data of the mth subchannel is A subcarrier to be transmitted is represented, and M represents the number of subcarriers selected from all Q subcarriers that can be used in the FFH-OFDM communication system.   In the fifth process, when the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the inverse fast Fourier transform subcarrier signal is multiplied by a preset diagonal matrix Hermitian and equalized. The method of claim 19. 21. The method according to claim 20, wherein the cyclic fast frequency hopping pattern is a fast frequency hopping pattern defined as in the following <Equation 42>.

In Equation 41, f _n of the high-speed frequency hopping pattern represents a subcarrier on which data of the first subchannel is transmitted in the nth sample. Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels that are a set of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) signal transmission device of communication system,
A first controller for inserting the input data into the remaining subcarriers at the selected subcarrier, wherein the input data is transmitted among all the available subcarriers;
A fast frequency hopper that assigns input data to a number of subcarriers selected from all available subcarriers and performs fast frequency hopping with a fast frequency hopping signal generated by a fast frequency hopping pattern;
A fast Fourier transformer for fast Fourier transforming the fast frequency hopped signal;
A second controller for inserting null data into the remaining subcarriers;
A first inverse carrier signal that receives the selected subcarrier signal having the input data and the remaining subcarrier signal with the null data inserted therein to generate a first IFFT signal and performs an inverse fast Fourier transform. A fast Fourier transformer;
A transmitter for transmitting the first inverse fast Fourier transform signal. The high-speed frequency hopper is
A second inverse fast Fourier transform that performs an inverse fast Fourier transform on the signal output from the first controller;
23. The apparatus according to claim 22, further comprising: a linear processor that linearly processes the subcarriers subjected to the inverse fast Fourier transform by the second inverse fast Fourier transformer so as to have a preset gain. The fast frequency hopping device is a fast frequency hopping matrix as shown in the following <Equation 42>.

24. The apparatus of claim 23, wherein high-speed frequency hopping is performed so as to correspond to.

In <Formula 42>, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n and m} are n-th samples and data of the m-th sub-channel is transmitted. Q represents the number of all usable subcarriers used in the FFH-OFDM communication system. The second inverse fast Fourier transform is an inverse fast Fourier transform matrix of a Q-point inverse fast Fourier transform of the following <Equation 43>.

25. The apparatus according to claim 24, wherein an inverse fast Fourier transform is performed on the subcarrier signals corresponding to the M subcarriers in a one-to-one correspondence with the subcarrier signals.

The linear processor is
When the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the subcarrier signal subjected to the inverse fast Fourier transform by the second inverse fast Fourier transform is multiplied by a preset diagonal matrix and linearly processed. 26. The apparatus of claim 25. 27. The apparatus according to claim 26, wherein the cyclic high-speed frequency hopping pattern is a high-speed frequency hopping pattern defined as in the following <Equation 44>.

In Equation 44, f _n of the high-speed frequency hopping pattern represents a subcarrier on which data of the first subchannel is transmitted in the nth sample. 28. The apparatus according to claim 27, wherein the diagonal matrix satisfies the following conditions of <Equation 45> and <Equation 46>.

In <Equation 45>, M represents the selected number,

Represents the diagonal matrix,

Represents the diagonal matrix when performing fast frequency hopping without inserting null data into the remaining subcarriers in the first step.

Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels that are a set of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) communication system signal transmission method,
A first step of inserting null data into the remaining subcarriers excluding selected subcarriers, wherein the input data is transmitted among all the usable subcarriers;
A second step of performing fast frequency hopping with a fast frequency hopping signal generated by a fast frequency hopping pattern by assigning input data to a number of subcarriers selected from all the available subcarriers;
A third step of fast Fourier transforming the fast frequency hopped signal;
A fourth step of inserting null data into the remaining subcarriers in the fast Fourier transformed signal;
A fifth process in which the fast Fourier transform selected subcarrier signal and the remaining subcarrier signal into which the null data is inserted in a fourth process are input to perform an inverse fast Fourier transform;
And a sixth step of transmitting the inverse fast Fourier transformed signal. The second process includes
A seventh step of performing an inverse fast Fourier transform on the signal generated in the first step;
An eighth step of linearly processing the subcarrier signal subjected to the inverse fast Fourier transform in the seventh step so as to have a preset gain;
30. The method of claim 29, comprising: The second step The method of claim 30, wherein the performing fast frequency hopping so as to correspond to the fast frequency hopping matrix G _Q such as <Equation 47> below.

In <Formula 47>, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n and m} are n-th samples and data of the m-th sub-channel is transmitted. Q represents the number of all usable subcarriers used in the FFH-OFDM communication system. The seventh step is a Q-point inverse fast Fourier transform matrix of the following <Formula 48>.

32. The method of claim 31, further comprising: performing an inverse fast Fourier transform on the subcarrier signal corresponding to the M subcarriers in a one-to-one correspondence with the M subcarriers.

  In the eighth step, when the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the subcarrier signal subjected to inverse fast Fourier transform by the second inverse fast Fourier transformer is multiplied by a preset diagonal matrix. The method of claim 32, wherein the method is linear. The method according to claim 33, wherein the cyclic fast frequency hopping pattern is a fast frequency hopping pattern defined as in the following <Equation 49>.

In Equation 49, f _n of the high-speed frequency hopping pattern represents a subcarrier on which data of the first subchannel is transmitted in the nth sample. 35. The method according to claim 34, wherein the diagonal matrix satisfies the following conditions of <Formula 50> and <Formula 51>.

In <Formula 50>, M represents the preset number of subcarriers,

Represents the diagonal matrix,

Represents the diagonal matrix when performing fast frequency hopping without inserting null data into the remaining subcarriers in the first step.

Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels that are a set of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) signal transmission device of communication system,
A first Fast Fourier Transform that fast Fourier transforms the received signal;
The transmission apparatus separates the remaining subcarriers excluding the selected subcarriers among the plurality of subcarriers, excluding the selected subcarriers, using the signal subjected to the fast Fourier transform in the first fast Fourier transformer. A first controller for inserting null data to correspond to the remaining subcarriers;
A first equalizer for equalizing the output signal of the first controller in a frequency domain;
An inverse fast Fourier transformer that performs an inverse fast Fourier transform on the signal equalized in the frequency domain, corresponding to a fast frequency hopping matrix applied to the transmitter;
A second equalizer for equalizing the inverse fast Fourier transformed signal in the time domain;
A second Fast Fourier Transform that fast Fourier transforms the equalized signal in the time domain;
And a second controller for separating the remaining subcarriers from the signal subjected to the fast Fourier transform by the second fast Fourier transformer and inserting null data into the remaining subcarriers. . 37. The apparatus of claim 36, wherein the fast frequency hopping matrix is expressed as in the following <Equation 52>.

In <Formula 52>,

Represents the fast frequency hopping matrix, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n, m} are the nth sample and the data of the mth subchannel is It represents the subcarriers to be transmitted, and Q represents the number of all usable subcarriers used in the FFH-OFDM communication system.   When the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the second equalizer performs equalization by multiplying the inverse fast Fourier transform subcarrier signal with a preset diagonal matrix of Hermitian. 38. The apparatus of claim 37. 39. The apparatus according to claim 38, wherein the cyclic fast frequency hopping pattern is a fast frequency hopping pattern defined as in the following <Formula 53>.

In <Equation 53> of the, f _n of the fast frequency hopping pattern represents the sub-carrier data of the first sub-channel is transmitted by the n-th sample. 40. The apparatus according to claim 39, wherein the diagonal matrix satisfies the following conditions of <Formula 54> and <Formula 55>.

In <Formula 54>, M represents the number of the set subcarriers.

Represents the diagonal matrix,

Represents the diagonal matrix when high-speed frequency hopping is performed without inserting null data into the remaining subcarriers.

Fast frequency hopping-Orthogonal Frequency Division Multiplexing (OFDM) comprising multiple subchannels that are a collection of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands Division Multiplexing) communication system transmission method,
A first process for fast Fourier transform of the received signal;
In the first step, the transmission apparatus uses the fast Fourier transform signal to separate the remaining subcarriers, excluding the selected subcarriers, from which the data has been transmitted, among the plurality of subcarriers, to separate the remaining subcarriers. A second process of inserting null data to correspond to
A third step of equalizing the signal generated in the second step;
A fourth step of performing an inverse fast Fourier transform on the frequency domain equalized signal so as to correspond to a fast frequency hopping matrix;
A fifth step of equalizing the inverse fast Fourier transformed signal in the time domain;
A sixth step of fast Fourier transforming the equalized signal in the time domain;
The sixth step includes a seventh step of separating a signal corresponding to the remaining subcarriers from the fast Fourier transformed signal and inserting null data so as to correspond to the remaining subcarriers. how to. 43. The method of claim 42, wherein the fast frequency hopping matrix is expressed as in the following <Formula 56>.

In the above <Formula 56>,

Represents the fast frequency hopping matrix, n represents a sample index (index), m represents a sub-channel index, and [Ф] _{n, m} are the nth sample and the data of the mth subchannel is It represents the subcarriers to be transmitted, and Q represents the number of all usable subcarriers used in the FFH-OFDM communication system.   In the fifth step, when the fast frequency hopping pattern is a cyclic fast frequency hopping pattern, the inverse fast Fourier transform subcarrier signal is multiplied by a preset diagonal matrix Hermian and equalized. 43. The method of claim 42. 44. The method according to claim 43, wherein the cyclic fast frequency hopping pattern is a fast frequency hopping pattern defined as in the following <Formula 57>.

In Equation 57, f _n of the high-speed frequency hopping pattern represents a subcarrier on which data of the first subchannel is transmitted in the nth sample. 45. The method according to claim 44, wherein the diagonal matrix satisfies the following conditions of <Formula 58> and <Formula 59>.

In <Formula 58>, M represents the number of the set subcarriers.

Represents the diagonal matrix,

Represents the diagonal matrix when performing fast frequency hopping without inserting null data into the remaining subcarriers in the first step.

Fast frequency hopping-orthogonal frequency division multiplexing (FFH-OFDM) comprising multiple subchannels that are a set of one or more subcarrier bands, dividing all available frequency bands into multiple subcarrier bands -Orthogonal Frequency Division Multiplexing) communication system signal receiver,
A high-speed frequency hopping processing unit that converts a signal transmitted for each user into high-speed frequency hopping and OFDM signals
The high-speed frequency hopping processing unit associates input data to be transmitted to a corresponding user for each user with a selected subcarrier that transmits the input data among the plurality of subcarriers, and then performs a first high-speed frequency hopping processing unit. Consists of a processor that performs high-speed frequency hopping to correspond to the frequency hopping pattern,
A multiplexer for multiplexing the signal of the high-speed frequency hopping processing unit;
A fast inverse Fourier transformer for fast inverse Fourier transforming the multiplexed signal;
And a transmitter for transmitting the fast inverse Fourier transformed signal. Each processor is
A second inverse fast Fourier transform that assigns the input data to the selected subcarrier and then performs an inverse fast Fourier transform on the subcarrier;
47. The apparatus according to claim 46, further comprising: a linear processor that linearly processes the subcarrier signal inversely fast Fourier transformed by the second inverse fast Fourier transformer so as to have a preset gain. Each processor is
A first controller that inserts null data into the remaining subcarriers excluding selected subcarriers, wherein the input data is transmitted among all the available subcarriers;
A second inverse fast Fourier transform that performs an inverse fast Fourier transform on the signal output from the first controller;
47. The apparatus according to claim 46, further comprising: a linear processor that linearly processes the subcarrier signal inversely fast Fourier transformed by the second inverse fast Fourier transformer so as to have a preset gain.

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