JP2002330112A - Ofdm digital signal repeater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress equivalent errors resulting from transmission line distortion and thermal noise, which occur during equalization of a receiving wave, in spite of the number of receiving antennas. SOLUTION: A receiving section 10 converts a receiving signal into a base band digital signal, performs quadrature detection and discrete Fourier- transform, and outputs carrier data of an OFDM wave. A local signal for this frequency conversion is fed by a synchronous circuit section 40. In a repeating process section 20, an equalization circuit 201 equalizes input carrier data, a discrimination circuit 202 discriminates the values of incoming data, and a pilot insertion circuit 203 newly inserts a previously prepared correct pilot into the carrier data. A transmission section 30 performs inverse discrete Fourier-transform and quadrature modulation on the carrier data that the correct pilot is newly inserted into, converts the data into an OFDM signal of a desired frequency, and then sends the signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to an OFDM digital signal repeater, and more particularly to an OFDM digital signal repeater.
The characteristic degradation caused by the thermal noise included in the DM signal and the characteristic degradation due to the influence of multipath are improved, and OFDM is improved.
The present invention relates to an OFDM digital signal repeater for improving the C / N ratio of each signal carrier so as to be constant.

[0002]

2. Description of the Related Art Conventionally, in relaying OFDM signals,
When the number of receiving antennas is one, a received signal is equalized, and a transmission signal obtained by performing discrete inverse Fourier transform on carrier data after the equalization processing is transmitted. FIG. 3 is a block diagram illustrating an OFDM digital signal repeater of the “OFDM digital signal repeater” disclosed in Japanese Patent Application No. 2001-67267.

The "OFDM digital signal repeater" of Japanese Patent Application No. 2001-67267 shown in FIG. 3 shows a case where a plurality of receiving antennas are provided. In this case, each system is designed so that the signal after the diversity combining is equalized. , And the signals of the respective systems are diversity-synthesized using the weights, and the carrier signal that has been subjected to the diversity synthesis and equalization processing is directly transmitted as a discrete inverse Fourier transform to transmit a transmission signal.

That is, the receiving unit 91 converts each of a plurality of systems of received signals received by a plurality of receiving antennas into a baseband digital signal, performs quadrature detection, and performs a discrete Fourier transform. The diversity synthesizing unit 92 synthesizes the plurality of baseband digital signals with diversity. The transmitting unit 93 performs discrete inverse Fourier transform on the carrier data after the diversity combination, and then performs quadrature modulation to convert the carrier data into an OFDM signal of a desired frequency. The carrier data combining coefficient calculator 95 calculates the frequency response of the transmission path for each system from the carrier data for each system, and calculates the weighting coefficient for each carrier used for the diversity combining from the frequency response.

[0005]

By the way, in the above-mentioned conventional OFDM digital signal repeater, Japanese Patent Application No. 2001-6.
7267, including the “OFDM digital signal relay device”, the case of receiving with one receiving antenna and the case of receiving with multiple antennas for diversity combining.
In each case, the received signal is equalized, and the carrier data subjected to the equalization processing is directly subjected to discrete inverse Fourier transform and transmitted. In this case, the characteristics of the relay signal have been improved by the equalization processing. However, in such equalization processing, transmission line distortion of the received wave of the relay device,
Since the effects of thermal noise cannot be completely eliminated, at least an equalization error has occurred.

In addition, the pilot extracted from the received wave of the repeater is also only subjected to the equalization process, despite being affected by the transmission line distortion and the thermal noise.
This pilot itself was transmitted with an equalization error occurring. This pilot is inserted in the transmission signal for use in the equalization process on the receiving side, and the receiving side determines which modulation level is inserted for which carrier of which symbol. It is already known.

The present invention has been made in view of the above-mentioned problems in the conventional OFDM digital signal repeater, and has been developed in consideration of the transmission line distortion generated when equalizing a received wave regardless of the number of receiving antennas. It is an object of the present invention to provide an OFDM digital signal repeater capable of suppressing an equalization error caused by noise and thermal noise.

[0008]

According to the present invention, in order to solve the above-mentioned problems, an OFDM digital signal repeater according to the first aspect of the present invention provides an OFDM digital signal repeater for relaying a transmission wave of an OFDM signal.
An analog / digital conversion means for converting a frequency of an OFDM signal received by one antenna into a baseband digital signal in a digital signal repeater;
After quadrature detection of the baseband digital signal, discrete Fourier transform means for performing discrete Fourier transform, equalizing means for equalizing the discrete Fourier transformed data, and transmission data of a higher-order station from the equalized data. Data determination means for estimating and determining, pilot insertion means for inserting a normal pilot into the data after the determination, and discrete inverse Fourier transform for performing a discrete inverse Fourier transform on the data in which the normal pilot is inserted into the data after the determination Means, orthogonal modulation means for orthogonally modulating the carrier data after the discrete inverse Fourier transform, and frequency conversion means for converting the orthogonally modulated baseband digital signal into an OFDM signal of a desired frequency. It was configured as a relay device. The desired frequency is, for example, the same frequency as the OFDM signal received from the upper station or an arbitrary frequency different from the frequency of the OFDM signal received from the upper station.

With this configuration, OFD
The M digital signal repeater converts the frequency of the OFDM signal received by one antenna, converts it to a baseband digital signal, performs quadrature detection on the baseband digital signal, performs a discrete Fourier transform, and performs the discrete Fourier transform. The data thus equalized can be subjected to an equalization process, and further, transmission data from an upper station can be estimated and determined from the equalized data, and a regular pilot can be inserted into the data after this determination.

[0010] Further, the data into which the normal pilot after the determination is inserted is subjected to a discrete inverse Fourier transform, and a baseband digital signal obtained by orthogonally modulating the carrier data after the discrete inverse Fourier transform is transformed into an OFDM signal of a desired frequency. , So that the OFDM signal can be relayed. Also, from the carrier data after equalization,
Once, the transmission data from the upper station is estimated and the data is determined, and the determined data can be used as the transmission data of the relay station, so that the transmission with the equalization error of the reception wave of the relay device reduced can be performed. Become. Furthermore, the pilot extracted from the received wave of the repeater is also replaced with the normal pilot and inserted into the transmission data, so that the transmission with the equalization error of the received wave of the repeater minimized is possible, and the characteristic of the upper station is obtained. It is possible to minimize the accumulation of the deterioration in the relay device.

According to another aspect of the present invention, there is provided an OFDM digital signal repeater for relaying a transmission wave of an OFDM signal. A plurality of receiving antennas for receiving, analog / digital converting means for converting each of the plurality of received signals received by the plurality of receiving antennas into a baseband digital signal, and quadrature detection of each of the baseband digital signals Discrete Fourier transform means for obtaining carrier data for each system of the OFDM signal by performing discrete Fourier transform afterwards, and frequency response calculation means for calculating a frequency response of a transmission path for each system from the carrier data for each system. ,
Weighting coefficient calculation means for calculating a weighting coefficient for each carrier used for diversity combining from the frequency response of the transmission path for each system, and diversity for combining the carrier data for each system using the weighting coefficient for each carrier Combining means, data determining means for estimating and determining transmission data of an upper station from the carrier data after the diversity combining, pilot inserting means for inserting a normal pilot into the carrier data after the data determination, Discrete inverse Fourier transform means for performing discrete inverse Fourier transform on data in which a normal pilot is inserted into the data, quadrature modulating means for orthogonally modulating the carrier data after the discrete inverse Fourier transform, and a baseband digital signal which is orthogonally modulated The signal to the desired frequency
OFD having frequency conversion means for converting to an FDM signal
It was configured as an M digital signal repeater.

With this configuration, OFD
The M digital signal repeater converts each of a plurality of reception signals received by a plurality of reception antennas for receiving a transmission wave of the OFDM signal into a baseband digital signal, and performs quadrature detection on each of the baseband digital signals. Thereafter, carrier data for each system of the OFDM signal is extracted by performing a discrete Fourier transform, a frequency response of a transmission line for each system is calculated from the carrier data for each system, and a transmission line for each system is calculated. The weighting coefficient for each carrier used for diversity combining is calculated from the frequency response of the above, the carrier data for each system is diversity-combined using the weighting coefficient for each carrier, and the higher-order station is obtained from the carrier data after the diversity combining. The transmission data is estimated and determined, and the carrier data after the data determination is correct. It can be inserted into the pilot.

The data into which the normal pilot is inserted is subjected to discrete inverse Fourier transform, the carrier data after the discrete inverse Fourier transform is orthogonally modulated, and the orthogonally modulated baseband digital signal is converted to a signal of a desired frequency. O
Since it can be converted to an FDM signal and transmitted,
The relay of the DM signal becomes possible. Further, it becomes possible to cope with the fading phenomenon of the OFDM signal, and it is also possible to improve the C / N ratio.

Further, in the present invention, in the OFDM digital signal repeater according to claim 1 or 2, the pilot inserting means includes a known control signal in the carrier data after data determination together with the normal pilot. The configuration is such that known data can be inserted.

With this configuration, it is possible to transmit known data including a known control signal while minimizing the equalization error of the received wave of the relay device.
It is possible to minimize accumulation of deterioration of the characteristics of the upper station in the relay device.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. (First Embodiment) FIG. 1 is a block diagram showing an overall configuration of an OFDM digital signal relay apparatus according to a first embodiment.

An OFDM digital signal relay apparatus according to the present invention corresponds to claim 1, wherein a receiving section 10 converts a received signal into a digital signal of an intermediate frequency, performs quadrature detection, and outputs the signal, and a relay processing section. 20, a transmission unit 30, and a synchronization circuit unit 40. Here, the receiving unit 10 includes a down converter 101, an A / D converter 102 (analog / digital conversion means), a quadrature detector 103, and a discrete Fourier transformer 104 (discrete Fourier transform means).

The relay processing unit 20 includes an equalizing circuit 201
(Equalizing means) and the determining circuit 202 (data determining means)
And a pilot insertion circuit 203 (pilot insertion means)
And Further, the transmitting unit 30 includes a discrete inverse Fourier transformer 301 (discrete inverse Fourier transform unit), a quadrature modulator 302 (quadrature modulating unit), a D / A converter 303,
And an up-converter 304 (frequency conversion means).

The function of the OFDM digital signal repeater according to the present embodiment will be described below. In the present invention, even when receiving with one receiving antenna as shown in the present embodiment, as described in a second embodiment described later, a plurality of Even when receiving with an antenna, from the carrier data after equalization, once estimate the transmission data from the upper station, and perform data determination, and use this determined data as the relay station transmission data. I have.

The OF extracted from the received wave of the relay device
The pilot of the DM wave is also inserted into the transmission data, replacing the regular pilot (pilot having no error) prepared by the relay apparatus. After that, this transmission data is subjected to a discrete inverse Fourier transform to form a transmission signal, which is then transmitted.

The above-mentioned pilot is inserted into the transmission signal for use in the equalization processing on the receiving side.
The receiving side knows in advance the correspondence between each of the carriers included in each of the symbols and the inserted modulation level. Incidentally, the discrete Fourier transform and discrete inverse Fourier transform of the OFDM signal carrier number K is performed by a discrete inverse Fourier transform of the frequency number N ₀ (IDFT, IFFT) and the discrete Fourier transform of the frequency number N ₀ (DFT, FFT) .
At this time, the relationship between the number of carriers K and the number of points N ₀ is expressed by the following equation (1).

K <N ₀ ... (1) The OFDM signal relay-transmitted in this apparatus is transmitted through the receiving unit 10, the relay processing unit 20, and the transmitting unit 30. In the receiving unit 10, the received OFDM signal is converted from an RF frequency band to a complex baseband signal in a down converter 101. The local signal L ₀ for this frequency conversion is supplied from the synchronization circuit unit 40. Further, in the A / D converter 102, the D / A
A / D conversion is performed by the sampling clock fs common to the converter 303. Further, the orthogonal detection is performed by the orthogonal detector 103, the discrete Fourier transform is performed by the discrete Fourier transformer 104, and the carrier data Y (k) of the OFDM wave is obtained.
(K = 0, 1, 2,..., K−1) are output.

Assuming that the transmission data is D (k), the frequency response of the input signal of the repeater is H (k), and the additional noise of the input signal of the repeater is N (k), the output data Y ( k) is represented by the following equation (2). However, in equation (2), the frequency response H (k) is
The frequency response acting on the carrier k is represented by the additive noise N (k)
Means the noise added to the carrier k, the output data Y (k), the frequency response H (k), and the additional noise N
(K) are all complex numbers.

Y (k) = H (k) D (k) + N (k) k = 0, 1, 2,..., K−1) Expression (2) OFDM wave input to the relay processing unit 20 The carrier data Y (k) is first input to the equalization circuit 201, where it undergoes equalization processing. The equalizer 201 estimates the frequency response H (k) of the transmission path of the relay station input signal. Incidentally, known data on the receiving side that can be used for estimating the frequency response of the transmission path is inserted into the OFDM wave, and this is called a pilot here.

The estimated value of the frequency response H (k) is obtained by complexly dividing the pilot value extracted from the received OFDM wave carrier data Y (k) by the known pilot value. The frequency response H (k) obtained by this
Is expressed as H ′ (k), the carrier data Y (k) of the received OFDM wave is further equalized by H ′ (k) by complex division, and the following (3)
The output data Z (k) of the equalization circuit 201 shown in the equation is obtained.

Z (k) = Y (k) / H ′ (k) = (H (k) D (k) / H ′ (k)) + N (k) / H ′ (k) ... (3) Expression Z (k) after equalization is input from the equalization circuit 201 to the determination circuit 202, and the transmission data (here,
(Meaning transmission data from a broadcast station or another relay station included in the received OFDM wave). Here, the determination of the transmission data is to estimate what value of the transmission data has been transmitted.

As can be seen from the equation (3), the data Z (k) after the equalization processing can take a value different from that of the transmission data due to the presence of a transmission path estimation error and additional noise. Therefore,
The determination circuit 202 estimates transmission data and performs data determination. Generally, in the determination of the transmission data, the transmission data having the smallest Euclidean distance from the value of the data Z (k) after the equalization processing is determined as the transmitted transmission data. The determination circuit 202 outputs the determination data D ′ (k).

[0028] Of the carriers included in the OFDM wave, the differentially modulated carrier is subjected to differential demodulation in the equalization circuit 201, and the determination circuit 202 estimates the transmission data after differential demodulation. And judgment are performed respectively. The determination data D ′ (k) is input from the determination circuit 202 to the pilot insertion circuit 203, and a pilot of a predetermined modulation level prepared in advance is newly inserted into a predetermined carrier in the predetermined symbol. .

As described above, by replacing a pilot with a correct pilot prepared in advance, a transmission path estimation error suffered by the pilot and the effect of additional noise are removed from the carrier, and a new signal after relaying is removed. It can be transmitted as a simple broadcast wave.

It is assumed that pilot control circuit 203 newly inserts a control signal of a correct modulation level for a predetermined carrier in a predetermined symbol of the OFDM wave for control signals other than pilot signals.

The transmitting section 30 has the decision data D 'after the correct pilot has been inserted and the data decision has been made.
(K) is input. This input judgment data D ′
(K) is subjected to a discrete inverse Fourier transform in a discrete Fourier transformer 301, orthogonally modulated in a quadrature modulator 302, and a D / A converter 303 using a sampling clock fs common to the A / D converter 102 of the receiving unit 10. D
/ A conversion. Then, the signal is converted into a desired transmission frequency in the up-converter 304 and transmitted as a radio wave or transmitted to another station via a cable.

In the synchronous circuit unit 40, the receiving unit 10
Local signal L for frequency conversion ₀Generate Ma
In the receiving unit 10, the relay processing unit 20, and the transmitting unit 30,
Generate a sampling clock fs to be used. Further
The window of the discrete Fourier transformer 104 of the receiving unit 10
C Symbol timing used to set the position
Generate a clock.

(Second Embodiment) FIG. 2 is a block diagram showing an overall configuration of an OFDM digital signal repeater according to a second embodiment. An OFDM digital signal relay apparatus according to the present embodiment corresponds to claim 2,
A diversity combining unit 2, a relay processing unit 20 ',
It has a transmission unit 3 and a synchronization circuit unit 4.

Here, the receiving unit 1 transmits the transmitted OF.
A plurality of antennas (space diversity antennas) for receiving a DM wave signal (high frequency) as reception signals of a plurality of systems of branches # 0 to # (L-1), and down converters 111 to ₁ corresponding to the plurality of antennas, respectively. 11 _L and A
/ D converter 12 ₁ to 12 _L and (analog / digital converter), comprising quadrature and detector 13 ₁ to 13 _L, and a discrete Fourier transformer 14 ₁ to 14 _L (discrete Fourier transform means)
L reception systems are configured.

The diversity combining section 2 includes a carrier data combining circuit 21 (diversity combining means). Further, the relay processing unit 20 ′ includes the same determination circuit 202 (data determination unit) and the pilot insertion circuit 203 (pilot insertion unit) as the OFDM digital signal relay device according to the first embodiment of the present invention. .

Further, the carrier data combining coefficient calculating section 5
Comprises a frequency response calculation circuit 51 (frequency response coefficient calculation means) and a frequency weighting coefficient calculation circuit 52 (weighting coefficient calculation means). Further, the transmitting unit 3 includes a discrete inverse Fourier transformer 31, a quadrature modulator 32 (quadrature modulation means), a D / A converter 33, and an up-converter 34.
(Frequency conversion means).

Hereinafter, the operation of the OFDM digital signal repeater according to the present embodiment will be described. In the receiving unit 1, the OFDM signals of the branches # 0 to # (L-1) of the number L of systems received by the plurality of space diversity antennas are the number of systems L (systems l = 0, 1, 2,..., L- 1) using a common local signal L ₀ in each system in a down-converter 11 ₁ to 11 _L is a frequency conversion circuit corresponding converted from the frequency band of the radio frequency (RF) into a complex baseband signal. After that, the A / D converter 12 corresponding to the number of systems L
_{In 1 to} 12 _L , an analog signal is converted into a digital signal by a sampling clock fs common to each system. Furthermore, after quadrature detection by the quadrature detector 13 ₁ to 13 _L, the number of systems by a discrete Fourier transformer 14 ₁ to 14 _L L
Fourier transform is performed for each carrier, and carrier data Dl (k) (k = 0, 1, 2,..., K−
1) is output.

The diversity combining section 2 assigns a weighting coefficient Wl (k) (k = 0, 1, 2,..., K−) for each carrier adapted to the signal characteristics of each input system from a plurality of antennas.
The signal indicating 1) is input from the frequency weighting coefficient calculating circuit 52, and the carrier data synthesizing circuit 21 outputs the signal indicating the weighting coefficient Wl (k) for each carrier and the carrier data Dl (of the OFDM signal for each system). k) and the product sum (inner product) of each system is calculated, and one system of carrier data as a result of the calculation (diversity combining) is output.

The decision circuit 202 of the relay processing unit 20 'receives the carrier data output from the diversity synthesizing unit 2 and receives the OFDM digital signal relay device according to the first embodiment of the present invention shown in FIG. Similarly, a correct pilot is inserted into the carrier data, and the data after data determination is output to transmitting section 3.

The transmitting section 3 subjects the carrier data after the diversity combining to discrete inverse Fourier transform by the discrete inverse Fourier transformer 31 and then orthogonally modulates by the quadrature modulator 32 to convert the carrier data into an OFDM signal of a desired frequency. After D / A conversion in the A converter 33, the signal is converted into a desired transmission frequency by the up-converter 34 and transmitted as radio waves or transmitted to another station via a cable.

The carrier data synthesizing coefficient calculating section 5 calculates the frequency response of the transmission line for each system from the carrier data for each system by the frequency response calculating circuit 51, and calculates the frequency weighting coefficient calculating circuit 52 from the frequency response. , A weighting coefficient for each carrier used for the diversity combining described above is calculated.

[0042]

As described above, according to the present invention, the O
The FDM digital signal repeater has the following excellent effects. In the OFDM digital signal repeater, 1
The frequency of the OFDM signal received by the antenna is converted to a baseband digital signal, the baseband digital signal is subjected to quadrature detection, discrete Fourier transform is performed, and the data subjected to the discrete Fourier transform is equalized. ,
Further, the transmission data of the upper station is estimated and determined from the data subjected to the equalization processing, and a normal pilot is inserted into the data after the determination. A baseband digital signal obtained by performing a discrete inverse Fourier transform and orthogonally modulating the carrier data after the discrete inverse Fourier transform is converted into an OFDM signal of a desired frequency and transmitted.

Therefore, the relay of the OFDM signal becomes possible, and the transmission with the equalization error of the received wave of the relay device minimized, and the accumulation of the deterioration of the characteristic of the upper station in the repeater device is minimized. It becomes possible. And, as a result, the OFDM received for relay
Characteristic degradation due to thermal noise of the signal and characteristic degradation due to the influence of multipath can be improved as compared to the conventional art, and the OFDM signal is transmitted with the C / N ratio of each carrier improved to be constant. It becomes possible.

In the OFDM digital signal repeater according to the present invention, each of a plurality of systems of received signals received by a plurality of receiving antennas for receiving a transmission wave of the OFDM signal is converted into a baseband digital signal. After quadrature detection of each of the band digital signals, discrete Fourier transform is performed to extract carrier data of the OFDM signal for each system, and calculate a frequency response of a transmission path for each system from the carrier data for each system. ,Also,
A weighting coefficient for each carrier used for diversity combining is calculated from the frequency response of the transmission path for each system, and the carrier data for each system is configured to perform diversity combining using the weighting coefficient for each carrier, and The transmission data of the upper station is estimated and determined from the carrier data after the diversity combining, and further, the data obtained by inserting a normal pilot into the carrier data after the data determination is subjected to discrete inverse Fourier transform, and the discrete inverse Fourier transform is performed. The converted carrier data is orthogonally modulated, and the orthogonally modulated baseband digital signal is converted into an OFDM signal of a desired frequency and transmitted.

Therefore, it becomes possible to relay the OFDM signal, to cope with the fading phenomenon of the OFDM signal, and to improve the C / N ratio. Further, it is possible to perform transmission while minimizing the equalization error of the received wave of the relay device, and it is possible to minimize the accumulation of the deterioration of the characteristics of the upper station in the relay device. As a result, it becomes possible to improve the characteristic degradation due to the thermal noise of the OFDM signal received for relaying and the characteristic degradation due to the influence of the multipath as compared with the conventional art. It is possible to improve the transmission so that the N ratio becomes constant and to transmit.

[Brief description of the drawings]

FIG. 1 shows an OFD according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating an overall configuration of an M digital signal relay device.

FIG. 2 shows an OFD according to a second embodiment of the present invention.
FIG. 2 is a block diagram illustrating an overall configuration of an M digital signal relay device.

FIG. 3 shows a conventional OFDM digital signal repeater;
FIG. 2 shows a block diagram of an FDM digital signal repeater.

[Explanation of symbols]

1, 10 receiving section, 2 diversity combining section, 3, 30 transmitting section, 4, 40 synchronous circuit section, 5 carrier data combining and counting section 20, 20 'relay processing section 21, carrier data synthesis circuit, 31, 301, discrete inverse Fourier transformer, 32, 302, quadrature modulator, 33, 303, D / A converter, 34, 304, up converter, 51 Frequency response calculation circuit 52, frequency weighting coefficient calculation circuit 101, 11 _{1 to} 11 _L down converter, 102, 12 _{1 to} 12 _L A / D converter, 103, 13 _{1 to} 13 _L. quadrature detector, 104,14 ₁ ~14 _L ...... discrete Fourier transformer, 201 ...... equalizer 202 ...... determination circuit 203 ...... pilot insertion circuit

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazuhiko Shibuya 1-10-11 Kinuta, Setagaya-ku, Tokyo Japan Broadcasting Research Institute F-Term (Reference) 5K022 DD01 DD18 DD23 DD33 DD34

Claims (3)

[Claims] An OFD for relaying a transmission wave of an OFDM signal
In an M digital signal repeater, an OFDM signal received by one antenna is frequency-converted, and then converted to a baseband digital signal.
Digital conversion means, after orthogonal detection of the baseband digital signal, discrete Fourier transform means for performing discrete Fourier transform, equalization means for equalizing the discrete Fourier-transformed data, and higher-order data from the equalized data. Data determination means for estimating and determining transmission data of a station; pilot insertion means for inserting a normal pilot into the data after the determination; discrete inverse Fourier transform of the data in which the normal pilot is inserted into the data after the determination. Discrete inverse Fourier transforming means, quadrature modulating means for orthogonally modulating the carrier data after the discrete inverse Fourier transform, and frequency converting means for converting the orthogonally modulated baseband digital signal into an OFDM signal of a desired frequency. An OFDM digital signal repeater, comprising: 2. An OFD for relaying a transmission wave of an OFDM signal.
In the M digital signal repeater, a plurality of reception antennas for receiving the transmission wave of the OFDM signal, and an analog / digital conversion for converting each of a plurality of reception signals received by the plurality of reception antennas into a baseband digital signal A discrete Fourier transform means for orthogonally detecting each of the baseband digital signals and then performing a discrete Fourier transform to obtain carrier data for each system of the OFDM signal; and for each system from the carrier data for each system. Frequency response calculating means for calculating the frequency response of the transmission path of the transmission path; weighting coefficient calculation means for calculating the weighting coefficient for each carrier used for diversity combining from the frequency response of the transmission path for each system; carrier data for each system Using the weighting factor for each carrier Diversity combining means, data determining means for estimating and determining transmission data of an upper station from the carrier data after the diversity combining, pilot inserting means for inserting a regular pilot into the carrier data after the data determination, Discrete inverse Fourier transform means for performing discrete inverse Fourier transform on data obtained by inserting a normal pilot into the subsequent data; orthogonal modulating means for orthogonally modulating the carrier data after the discrete inverse Fourier transform; Frequency conversion means for converting a band digital signal into an OFDM signal having a desired frequency. An OFDM digital signal relay device comprising: 3. The apparatus according to claim 1, wherein the pilot insertion unit inserts known data including a known control signal into the carrier data after the data determination together with the normal pilot. OFDM digital signal repeater.