JP3661092B2 - Orthogonal frequency division multiplex signal receiving apparatus and orthogonal frequency division multiplex signal receiving method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an orthogonal frequency division multiplexing signal receiving apparatus that receives a signal subjected to orthogonal frequency division multiplexing and decodes transmission data, and more particularly to decode transmission data by appropriately equalizing a reception signal. The present invention relates to an orthogonal frequency division multiplex signal receiving apparatus that can be used.
[0002]
[Prior art]
An orthogonal frequency division multiplex (OFDM) method is known as one of digital signal transmission methods. Some of the orthogonal frequency division multiplexing systems transmit data by inserting pilot signals generated with predetermined amplitude, phase and timing into predetermined subcarriers.
For example, in a system for synchronous modulation in DVB-T (Digital Video Broadcasting-Terrestrial) and ISDB-T (Integrated Services Digital Broadcasting-Terrestrial) using orthogonal frequency division multiplexing, an SP (Scattered Pilot) signal and A so-called pilot signal is used.
[0003]
Here, for example, a receiving apparatus that is applied to a DVB-T system and receives an orthogonal frequency division multiplex signal and decodes transmission data with a configuration using an equalizer, first, based on the received signal data, an SP signal The transmission path characteristics for the subcarriers that transmitted are obtained. Next, the receiving apparatus filters data indicating transmission path characteristics in a symbol direction (time direction) and a subcarrier direction (frequency direction) using a symbol filter and a subcarrier filter, respectively. As a result, the channel characteristics specified only for the subcarriers that transmitted the SP signal are interpolated and interpolated to obtain channel characteristics data indicating the channel characteristics for all subcarriers.
[0004]
The receiving apparatus obtains the received signal data equalized corresponding to the influence of the transmission path (for example, fading) by dividing the received signal data using the transmission path characteristic data thus obtained. The transmission data can be decoded by demapping or the like.
[0005]
[Problems to be solved by the invention]
In the above prior art, normally, the transmission path characteristic data specified for the subcarrier on which the SP signal is transmitted is interpolated by interpolating in the symbol direction (time direction) using a symbol filter, and then LPF (Low Pass). Is interpolated by interpolating in the subcarrier direction (frequency direction) by a subcarrier filter composed of (Filter).
[0006]
At this time, it is difficult to make the LPF used as a subcarrier filter have ideal frequency characteristics. In other words, the LPF ideally has a step-like low-pass characteristic with a predetermined frequency as the high-frequency cutoff frequency. However, in reality, it is difficult to obtain such characteristics, and ripples (pulsations) and finite inclinations often occur in the frequency characteristics.
For this reason, the transmission path characteristic data is distorted, and the received signal data cannot be properly equalized.
[0007]
The present invention has been made in view of the above circumstances, and an object thereof is to provide an orthogonal frequency division multiplex signal receiving apparatus capable of accurately specifying the characteristics of a transmission path and appropriately equalizing a received signal. And
[0008]
[Means for Solving the Problems]
In order to achieve the above object, an orthogonal frequency division multiplex signal receiving apparatus according to a first aspect of the present invention provides:
Obtaining the characteristics of the transmission path based on the distributed pilot signal inserted and transmitted in a predetermined subcarrier, equalizing the received signal data according to the transmission path characteristics, decoding the transmission data,
A transmission path characteristic for a subcarrier that has transmitted a distributed pilot signal is specified, and filtering processing is performed to obtain data indicating transmission path characteristics corresponding to all subcarriers based on the data indicating the specified transmission path characteristics. In addition, the amount of change in the data level before and after the filtering process is detected, the data indicating the transmission path characteristics is corrected based on the detection result, and the received signal data is equalized using the corrected data.
It is characterized by that.
[0009]
According to the present invention, it is possible to detect the amount of change in the data level before and after the filtering process for obtaining the data indicating the transmission path characteristics corresponding to all the subcarriers, and to correct the data indicating the transmission path characteristics. .
As a result, it is possible to correct data distortion caused by filtering processing, accurately specify the characteristics of the transmission path, and appropriately equalize the received signal.
[0010]
An orthogonal frequency division multiplex signal receiver according to a second aspect of the present invention provides:
Receiving received signal data indicating an orthogonal frequency division multiplexed signal in which a distributed pilot signal is inserted in a predetermined subcarrier, and decoding transmission data;
Fourier transform means for Fourier transforming input received signal data;
Based on the received signal data Fourier-transformed by the Fourier transform means, characteristic specifying means for specifying the transmission path characteristics for the subcarriers that transmitted the dispersed pilot signal;
First interpolation means for interpolating data indicating transmission path characteristics specified by the characteristic specifying means in a symbol direction;
Second interpolation means for interpolating data indicating transmission path characteristics interpolated in the symbol direction by the first interpolation means in the subcarrier direction;
First detection means for detecting a data level of data indicating transmission path characteristics interpolated in the symbol direction by the first interpolation means;
Second detection means for detecting a data level of data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means;
Characteristic correction means for correcting data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means based on detection results by the first and second detection means;
Signal equalization means for equalizing the received signal data Fourier-transformed by the Fourier transform means, using data indicating the transmission path characteristics corrected by the characteristic correction means;
Demapping means for decoding transmission data from reception signal data equalized by the signal equalization means,
It is characterized by that.
[0011]
According to this invention, the data level before and after the second interpolation means interpolates the data indicating the transmission path characteristics in the subcarrier direction is detected using the first and second detection means. The characteristic correction means is generated when the second interpolation means interpolates the data by correcting the data interpolated by the second interpolation means based on the detection results by the first and second detection means. Data distortion can be corrected.
As a result, it is possible to accurately identify the characteristics of the transmission path and appropriately equalize the received signal.
[0012]
More specifically, the first detection means detects a data level of data indicating transmission path characteristics with respect to subcarriers transmitting a distributed pilot signal among the data interpolated in the symbol direction by the first interpolation means. And
Preferably, the second detection means detects a data level of data indicating a transmission path characteristic for a subcarrier transmitting a distributed pilot signal among the data interpolated in the subcarrier direction by the second interpolation means. .
[0013]
The characteristic correction means includes
Division processing means for dividing a level value indicating the data level detected by the first detection means by a level value indicating the data level detected by the second detection means;
The correction result is obtained by averaging the division results by the division processing means, and the transmission line characteristic is shown by multiplying the data indicating the transmission line characteristic corresponding to all the subcarriers with the fixed correction data. It is desirable to provide product processing means for correcting data.
[0014]
An orthogonal frequency division multiplex signal receiver according to a third aspect of the present invention provides:
Receiving received signal data indicating an orthogonal frequency division multiplexed signal in which a distributed pilot signal is inserted in a predetermined subcarrier, and decoding transmission data;
Fourier transform means for Fourier transforming input received signal data;
Based on the received signal data Fourier-transformed by the Fourier transform means, characteristic specifying means for specifying the transmission path characteristics for the subcarriers that transmitted the dispersed pilot signal;
First interpolation means for interpolating data indicating transmission path characteristics specified by the characteristic specifying means in a symbol direction;
Second interpolation means for interpolating data indicating transmission path characteristics interpolated in the symbol direction by the first interpolation means in the subcarrier direction;
First detecting means for detecting a data level of data indicating the transmission path characteristics specified by the characteristic specifying means;
Second detection means for detecting a data level of data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means;
Characteristic correction means for correcting data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means based on detection results by the first and second detection means;
Signal equalization means for equalizing the received signal data Fourier-transformed by the Fourier transform means, using data indicating the transmission path characteristics corrected by the characteristic correction means;
Demapping means for decoding transmission data from reception signal data equalized by the signal equalization means,
It is characterized by that.
[0015]
According to this invention, the first and second interpolation means detect the data level before and after interpolating the data indicating the transmission path characteristics using the first and second detection means. The characteristic correction unit corrects the data interpolated by the second interpolation unit based on the detection results of the first and second detection units, whereby the first and second interpolation units interpolate the data. It is possible to correct the distortion of the data generated in the above.
As a result, it is possible to accurately identify the characteristics of the transmission path and appropriately equalize the received signal.
[0016]
An orthogonal frequency division multiplex signal receiving method according to a fourth aspect of the present invention is:
A method for decoding transmission data from received signal data indicating an orthogonal frequency division multiplexed signal in which a distributed pilot signal is inserted in a predetermined subcarrier,
A Fourier transform step for Fourier transforming the received signal data;
Based on the received signal data Fourier-transformed in the Fourier transform step, a characteristic specifying step for specifying a transmission path characteristic for a subcarrier that has transmitted a distributed pilot signal;
A first interpolation step for interpolating data indicating transmission path characteristics specified in the characteristic specifying step in a symbol direction;
A second interpolation step for interpolating in the subcarrier direction the data indicating the transmission path characteristics interpolated in the symbol direction in the first interpolation step;
A first detection step of detecting a data level of the data interpolated in the symbol direction in the first interpolation step;
A second detection step of detecting a data level of the data interpolated in the subcarrier direction in the second interpolation step;
A characteristic correction step of correcting data indicating transmission path characteristics interpolated in the subcarrier direction in the second interpolation step based on the detection results in the first and second detection steps;
Using the data corrected in the characteristic correction step, a signal equalization step for equalizing the received signal data Fourier-transformed in the Fourier transform step;
A demapping step of decoding transmission data from the received signal data equalized in the signal equalization step,
It is characterized by that.
[0017]
An orthogonal frequency division multiplex signal receiving method according to a fifth aspect of the present invention provides:
A method for decoding transmission data from received signal data indicating an orthogonal frequency division multiplexed signal in which a distributed pilot signal is inserted in a predetermined subcarrier,
A Fourier transform step for Fourier transforming the received signal data;
Based on the received signal data Fourier-transformed in the Fourier transform step, a characteristic specifying step for specifying a transmission path characteristic for a subcarrier that has transmitted a distributed pilot signal;
A first interpolation step for interpolating data indicating transmission path characteristics specified in the characteristic specifying step in a symbol direction;
A second interpolation step for interpolating in the subcarrier direction the data indicating the transmission path characteristics interpolated in the symbol direction in the first interpolation step;
A first detection step of detecting a data level of data indicating the transmission path characteristics identified in the characteristic identification step;
A second detection step of detecting a data level of the data interpolated in the subcarrier direction in the second interpolation step;
A characteristic correction step of correcting data indicating transmission path characteristics interpolated in the subcarrier direction in the second interpolation step based on the detection results in the first and second detection steps;
Using the data corrected in the characteristic correction step, a signal equalization step for equalizing the received signal data Fourier-transformed in the Fourier transform step;
A demapping step of decoding transmission data from the received signal data equalized in the signal equalization step,
It is characterized by that.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an orthogonal frequency division multiplex signal receiving apparatus 100 according to an embodiment of the present invention will be described in detail with reference to the drawings.
[0019]
An orthogonal frequency division multiplexing signal receiving apparatus 100 according to an embodiment of the present invention receives, for example, baseband received signal data obtained by detection by an orthogonal detector, and decodes (restores) transmission data transmitted from the transmission side. )
Here, the signal detected by the quadrature detector is, for example, an IF (Intermediate Frequency) signal received by an antenna, down-converted, and digitized by an ADC (Analog / Digital Converter).
[0020]
The reception signal data input to the orthogonal frequency division multiplexing signal receiving apparatus 100 is subjected to orthogonal frequency division multiplexing on the transmission side, and is transmitted using a number of subcarriers orthogonal to each other at a symbol period. Is digitized data.
[0021]
In this orthogonal frequency division multiplexing signal, a known subcarrier having a period of 4 symbols in the symbol direction (time direction) and a period of 12 subcarriers in the subcarrier direction (frequency direction) is known on the receiving side. An SP (Scattered Pilot) signal having an amplitude and a phase is inserted.
[0022]
In order to receive such orthogonal frequency division multiplexing signals and decode transmission data, the orthogonal frequency division multiplexing signal receiving apparatus 100 includes an FFT (Fast Fourier Transform) circuit 10 as illustrated in FIG. An equalization processing unit 11 and a demapper circuit 12 are provided.
[0023]
The FFT circuit 10 is for performing Fourier transform on the received signal data to convert the time-series data on the time axis into the frequency component data on the frequency axis. The received signal data converted into the frequency component data is To the processing unit 11.
[0024]
The equalization processing unit 11 performs an equalization process on the received signal data, and corrects the received signal data deteriorated due to the influence of the transmission path (for example, fading).
As shown in FIG. 2, the equalization processing unit 11 includes a characteristic data calculation processing unit 20, a symbol direction interpolation processing unit 21, a subcarrier direction interpolation processing unit 22, a first and second level detection unit 23, 24, a division processing unit 25, a characteristic data correction processing unit 26, and an equalization calculation processing unit 27.
[0025]
The characteristic data calculation processing unit 20 is, for example, data indicating a reference SP signal generated at a predetermined timing by extracting a subcarrier transmitting the SP signal from the received signal data Fourier-transformed by the FFT circuit 10. By performing complex division, transmission line characteristic data indicating the characteristic of the transmission line is generated.
At this time, the characteristic data calculation processing unit 20 obtains the transmission line characteristic data indicating the transmission line characteristic in the subcarrier transmitting the SP signal by complex division, and inserts zero as the transmission line characteristic data for other subcarriers. .
[0026]
The symbol direction interpolation processing unit 21 is configured by using, for example, a FIR (Finite Impulse Response) filter or an IIR (Infinite Impulse Response) filter, and is specified for the subcarrier to which the SP signal is transmitted by the characteristic data calculation processing unit 20. The obtained transmission path characteristic data is interpolated in the symbol direction (time direction).
[0027]
The subcarrier direction interpolation processing unit 22 is configured by, for example, an LPF (Low Pass Filter) or the like, and the transmission path characteristic data interpolated in the symbol direction (time direction) by the symbol direction interpolation processing unit 21 is subcarrier direction (frequency direction). Is used to generate transmission line characteristic data for all subcarriers.
[0028]
The first level detection unit 23 detects the data level of the transmission line characteristic data interpolated in the symbol direction (time direction) by the symbol direction interpolation processing unit 21 and corresponding to the subcarrier transmitting the SP signal. Is for.
[0029]
The second level detection unit 24 determines the data level of the transmission path specifying data interpolated in the subcarrier direction (frequency direction) by the subcarrier direction interpolation processing unit 22 and corresponding to the subcarrier transmitting the SP signal. It is for detection.
[0030]
The division processing unit 25 generates correction data for correcting the transmission line characteristic data based on the data level of the transmission line characteristic data detected by the first and second level detection units 23 and 24. is there. That is, the division processing unit 25 divides the level value indicating the data level detected by the first level detection unit 23 by the level value indicating the data level detected by the second level detection unit 24, thereby correcting the corrected data. Is generated.
[0031]
The characteristic data correction processing unit 26 is composed of, for example, a multiplier, and the transmission line characteristic data obtained for all subcarriers by the subcarrier direction interpolation processing unit 22 is used as the correction data generated by the division processing unit 25. It is for use and correction.
For example, the characteristic data correction processing unit 26 averages the correction data generated by the division processing unit 25 based on the data level of the transmission path characteristic data corresponding to the subcarrier that transmitted the SP signal, and corresponds to all the subcarriers. The level change of the transmission line characteristic data is corrected by multiplying the transmission line characteristic data by fixed correction data.
[0032]
The equalization calculation processing unit 27 includes a numerical calculation circuit and the like, and uses the transmission path characteristic data corrected by the characteristic data correction processing unit 26 to perform complex division such as complex division on the received signal data received from the FFT circuit 10. This is for equalizing the received signal data by executing the calculation.
[0033]
The demapper circuit 12 shown in FIG. 1 is composed of, for example, a ROM (Read Only Memory) or the like, and decodes transmission data from the received signal data equalized by the equalization processing unit 11 based on the symbol layout on the complex plane. This is for executing the demapping process.
That is, the demapper circuit 12 corresponds to the correspondence between the coordinate value predetermined on the complex plane and the transmission data from the in-phase component and the quadrature component of the received signal data modulated by the multi-level modulation method such as 64QAM (Quadrature Amplitude Modulation). Based on the relationship, the transmission data is decoded.
The demapper circuit 12 outputs the decoded transmission data to a deinterleave circuit or the like, and uses the transmission data for processing.
[0034]
The operation of orthogonal frequency division multiplex signal receiving apparatus 100 according to the embodiment of the present invention will be described below.
When this orthogonal frequency division multiplex signal receiving apparatus 100 decodes transmission data, first, the FFT circuit 10 receives the received signal data obtained by the detection of the orthogonal detector and applies a Fourier transform to obtain the frequency from the time series data. Convert to component data.
The FFT circuit 10 sends the received signal data as frequency component data to the equalization processing unit 11.
[0035]
Next, the equalization processing unit 11 executes a process for equalizing the received signal data received from the FFT circuit 10.
FIG. 3 is a diagram illustrating the configuration of an orthogonal frequency division multiplexed signal indicated by the received signal data input to the equalization processing unit 11.
[0036]
In FIG. 3, the subcarriers with the suffix SP are subcarriers into which SP signals are inserted on the transmission side.
That is, the SP signal is transmitted after being inserted into a predetermined subcarrier having a period of 4 symbols in the symbol direction (time direction) and a period of 12 symbols in the subcarrier direction (frequency direction).
[0037]
The characteristic data calculation processing unit 20, for example, generates a reference SP signal in which a subcarrier (indicated by the suffix SP in FIG. 3) that transmits the SP signal is generated on the receiving side with a known amplitude, phase, and timing. Complex division by. Thereby, the transmission path characteristic corresponding to the subcarrier which transmitted SP signal can be calculated | required.
[0038]
The characteristic data calculation processing unit 20 sends transmission path characteristic data indicating the transmission path characteristics obtained for the subcarrier that transmitted the SP signal to the symbol direction interpolation processing unit 21. At this time, the characteristic data calculation processing unit 20 inserts zero as transmission line characteristic data for subcarriers other than the subcarrier that transmitted the SP signal, and sends it to the symbol direction interpolation processing unit 21.
[0039]
The symbol direction interpolation processing unit 21 performs a filtering process for interpolating the transmission path characteristic data received from the characteristic data calculation processing unit 20 in the symbol direction (time direction), and for the subcarriers marked with * in FIG. Obtain the transmission line characteristics. The symbol direction interpolation processing unit 21 sends the transmission path characteristic data interpolated in the symbol direction (time direction) to the subcarrier direction interpolation processing unit 22.
[0040]
Here, the first level detection unit 23 detects the data level of the transmission path characteristic data sent from the symbol direction interpolation processing unit 21 to the subcarrier direction interpolation processing unit 22 and notifies the division processing unit 25 of the data level.
[0041]
The subcarrier direction interpolation processing unit 22 performs a filtering process for interpolating the transmission path characteristic data received from the symbol direction interpolation processing unit 21 in the subcarrier direction (frequency direction). Obtain the channel characteristics for the carrier.
The subcarrier direction interpolation processing unit 22 sends the transmission path characteristic data interpolated in the subcarrier direction (frequency direction) to the characteristic data correction processing unit 26.
[0042]
Here, the second level detection unit 24 detects the data level of the transmission path characteristic data sent from the subcarrier direction interpolation processing unit 22 to the characteristic data correction processing unit 26 and notifies the division processing unit 25 of the data level.
[0043]
Since the subcarrier direction interpolation processing unit 22 only interpolates the transmission path characteristic data in the subcarrier direction (frequency direction), the transmission path characteristic data for the subcarrier transmitting the SP signal does not change before and after the filtering process. Is ideal.
However, actually, when the transmission path characteristic data is interpolated in the subcarrier direction, the transmission path characteristic data of the subcarrier that transmitted the SP signal is caused by the filtering process executed by the subcarrier direction interpolation processing unit 22. Data level may change.
[0044]
Therefore, the division processing unit 25 performs SP based on the data level of the transmission path characteristic data detected by the first level detection unit 23 and the data level of the transmission path characteristic data detected by the second level detection unit 24. The fluctuation amount of the transmission path characteristic data for the subcarrier that transmitted the signal is specified. That is, the division processing unit 25 sets the level value indicating the data level of the transmission line characteristic data notified from the first level detection unit 23 to the data level of the transmission line characteristic data notified from the second level detection unit 24. By performing complex division by the level value indicating, the amount of fluctuation of the transmission path characteristic data for the subcarrier transmitting the SP signal is specified.
The division processing unit 25 notifies the characteristic data correction processing unit 26 of the specified fluctuation amount of the transmission path characteristic data as correction data.
[0045]
The characteristic data correction processing unit 26 corrects the transmission path characteristic data received from the subcarrier direction interpolation processing unit 22 based on the fluctuation amount of the transmission path characteristic data notified from the division processing unit 25. That is, for example, the characteristic data correction processing unit 26 averages the correction data received from the division processing unit 25, and multiplies all the transmission line characteristic data by a certain amount of correction data. Correct level changes.
The characteristic data correction processing unit 26 sends the corrected transmission path characteristic data to the equalization calculation processing unit 27.
[0046]
The equalization arithmetic processing unit 27 equalizes the received signal data by performing complex division on the received signal data received from the FFT circuit 10 using the transmission path characteristic data received from the characteristic data correction processing unit 26.
The equalization arithmetic processing unit 27 sends the received signal data subjected to the equalization processing to the demapper circuit 12.
[0047]
The demapper circuit 12 decodes the transmission data using the received signal data that has been equalized by the equalization processing unit 11, and outputs the decoded data to a circuit that processes the transmission data such as a deinterleave circuit.
[0048]
As described above, according to the present invention, the data level of the channel characteristic data sent from the symbol direction interpolation processing unit 21 to the subcarrier direction interpolation processing unit 22 and the characteristic data correction processing from the subcarrier direction interpolation processing unit 22 are described. The data level of the transmission path characteristic data sent to the unit 26 is detected. Then, the level change of the transmission path characteristic data is corrected based on the detected data level.
That is, by detecting the data level of the transmission path characteristic data before and after being interpolated in the subcarrier direction (frequency direction) by the subcarrier direction interpolation processing unit 22, it is caused by the filtering processing executed by the subcarrier direction interpolation processing unit 22. It is possible to correct distortion of transmission path characteristic data.
As a result, the characteristics of the transmission path can be accurately specified, and the received signal can be appropriately equalized.
[0049]
The present invention is not limited to the above embodiment, and various modifications and applications are possible.
For example, in the above embodiment, the first level detection unit 23 has been described as detecting the data level of the transmission path characteristic data sent from the symbol direction interpolation processing unit 21 to the subcarrier direction interpolation processing unit 22, It is not limited to this.
That is, for example, as shown in FIG. 4, the first level detection unit 23 may detect the data level of the transmission line characteristic data sent from the characteristic data calculation processing unit 20 to the symbol direction interpolation processing unit 21. Good.
As a result, it is possible to detect a change in the level of the transmission line characteristic data due to the filtering process executed by the symbol direction interpolation processing unit 21 and correct the distortion of the transmission line characteristic data.
[0050]
【The invention's effect】
As described above, according to the present invention, it is possible to detect a level change caused by a filtering process for interpolating data indicating transmission path characteristics and correct data distortion. And the received signal can be appropriately equalized.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an orthogonal frequency division multiplex signal receiving apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a configuration of an equalization processing unit.
FIG. 3 is a diagram illustrating a configuration of an orthogonal frequency division multiplexing signal.
FIG. 4 is a diagram showing a modification of the orthogonal frequency division multiplex signal receiving apparatus according to the embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 FFT circuit 11 Equalization process part 12 Demapper circuit 20 Characteristic data calculation process part 21 Symbol direction interpolation process part 22 Subcarrier direction interpolation process part 23, 24 Level detection part 25 Division process part 26 Characteristic data correction process part 27 Equalization calculation Processing part

Claims (7)

Orthogonal frequency division multiplex signal reception that obtains transmission path characteristics based on distributed pilot signals inserted into a predetermined subcarrier and transmits the received signal data according to the transmission path characteristics and then decodes the transmission data A device,
A transmission path characteristic for a subcarrier that has transmitted a distributed pilot signal is specified, and filtering processing is performed to obtain data indicating transmission path characteristics corresponding to all subcarriers based on the data indicating the specified transmission path characteristics. In addition, the amount of change in the data level before and after the filtering process is detected, the data indicating the transmission path characteristics is corrected based on the detection result, and the received signal data is equalized using the corrected data.
An orthogonal frequency division multiplex signal receiving apparatus. An orthogonal frequency division multiplex signal receiving apparatus for inputting received signal data indicating an orthogonal frequency division multiplex signal in which a distributed pilot signal is inserted in a predetermined subcarrier and decoding transmission data,
Fourier transform means for Fourier transforming input received signal data;
Based on the received signal data Fourier-transformed by the Fourier transform means, characteristic specifying means for specifying the transmission path characteristics for the subcarriers that transmitted the dispersed pilot signal;
First interpolation means for interpolating data indicating transmission path characteristics specified by the characteristic specifying means in a symbol direction;
Second interpolation means for interpolating data indicating transmission path characteristics interpolated in the symbol direction by the first interpolation means in the subcarrier direction;
First detection means for detecting a data level of data indicating transmission path characteristics interpolated in the symbol direction by the first interpolation means;
Second detection means for detecting a data level of data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means;
Characteristic correction means for correcting data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means based on detection results by the first and second detection means;
Signal equalization means for equalizing the received signal data Fourier-transformed by the Fourier transform means, using data indicating the transmission path characteristics corrected by the characteristic correction means;
Demapping means for decoding transmission data from reception signal data equalized by the signal equalization means,
An orthogonal frequency division multiplex signal receiving apparatus. The first detecting means detects a data level of data indicating a transmission path characteristic for a subcarrier transmitting a distributed pilot signal among the data interpolated in the symbol direction by the first interpolation means,
The second detection means detects a data level of data indicating a transmission path characteristic for a subcarrier transmitting a distributed pilot signal among data interpolated in the subcarrier direction by the second interpolation means.
The orthogonal frequency division multiplex signal receiver according to claim 2. The characteristic correction means includes
Division processing means for dividing a level value indicating the data level detected by the first detection means by a level value indicating the data level detected by the second detection means;
The correction result is obtained by averaging the division results by the division processing means, and the transmission line characteristic is shown by multiplying the data indicating the transmission line characteristic corresponding to all the subcarriers with the fixed correction data. Product processing means for correcting data,
The orthogonal frequency division multiplex signal receiving apparatus according to claim 2 or 3, An orthogonal frequency division multiplex signal receiving apparatus for inputting received signal data indicating an orthogonal frequency division multiplex signal in which a distributed pilot signal is inserted in a predetermined subcarrier and decoding transmission data,
Fourier transform means for Fourier transforming input received signal data;
Based on the received signal data Fourier-transformed by the Fourier transform means, characteristic specifying means for specifying the transmission path characteristics for the subcarriers that transmitted the dispersed pilot signal;
First interpolation means for interpolating data indicating transmission path characteristics specified by the characteristic specifying means in a symbol direction;
Second interpolation means for interpolating data indicating transmission path characteristics interpolated in the symbol direction by the first interpolation means in the subcarrier direction;
First detecting means for detecting a data level of data indicating the transmission path characteristics specified by the characteristic specifying means;
Second detection means for detecting a data level of data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means;
Characteristic correction means for correcting data indicating transmission path characteristics interpolated in the subcarrier direction by the second interpolation means based on detection results by the first and second detection means;
Signal equalization means for equalizing the received signal data Fourier-transformed by the Fourier transform means, using data indicating the transmission path characteristics corrected by the characteristic correction means;
Demapping means for decoding transmission data from reception signal data equalized by the signal equalization means,
An orthogonal frequency division multiplex signal receiving apparatus. An orthogonal frequency division multiplexing signal reception method for decoding transmission data from reception signal data indicating an orthogonal frequency division multiplexing signal in which a distributed pilot signal is inserted into a predetermined subcarrier,
A Fourier transform step for Fourier transforming the received signal data;
Based on the received signal data Fourier-transformed in the Fourier transform step, a characteristic specifying step for specifying a transmission path characteristic for a subcarrier that has transmitted a distributed pilot signal;
A first interpolation step for interpolating data indicating transmission path characteristics specified in the characteristic specifying step in a symbol direction;
A second interpolation step for interpolating in the subcarrier direction the data indicating the transmission path characteristics interpolated in the symbol direction in the first interpolation step;
A first detection step of detecting a data level of the data interpolated in the symbol direction in the first interpolation step;
A second detection step of detecting a data level of the data interpolated in the subcarrier direction in the second interpolation step;
A characteristic correction step of correcting data indicating transmission path characteristics interpolated in the subcarrier direction in the second interpolation step based on the detection results in the first and second detection steps;
Using the data corrected in the characteristic correction step, a signal equalization step for equalizing the received signal data Fourier-transformed in the Fourier transform step;
A demapping step of decoding transmission data from the received signal data equalized in the signal equalization step,
An orthogonal frequency division multiplex signal receiving method. An orthogonal frequency division multiplexing signal reception method for decoding transmission data from reception signal data indicating an orthogonal frequency division multiplexing signal in which a distributed pilot signal is inserted into a predetermined subcarrier,
A Fourier transform step for Fourier transforming the received signal data;
Based on the received signal data Fourier-transformed in the Fourier transform step, a characteristic specifying step for specifying a transmission path characteristic for a subcarrier that has transmitted a distributed pilot signal;
A first interpolation step for interpolating data indicating transmission path characteristics specified in the characteristic specifying step in a symbol direction;
A second interpolation step for interpolating in the subcarrier direction the data indicating the transmission path characteristics interpolated in the symbol direction in the first interpolation step;
A first detection step of detecting a data level of data indicating the transmission path characteristics identified in the characteristic identification step;
A second detection step of detecting a data level of the data interpolated in the subcarrier direction in the second interpolation step;
A characteristic correction step of correcting data indicating transmission path characteristics interpolated in the subcarrier direction in the second interpolation step based on the detection results in the first and second detection steps;
Using the data corrected in the characteristic correction step, a signal equalization step for equalizing the received signal data Fourier-transformed in the Fourier transform step;
A demapping step of decoding transmission data from the received signal data equalized in the signal equalization step,
An orthogonal frequency division multiplex signal receiving method.

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