JP4460738B2 - 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 restores transmission data, and in particular, can appropriately equalize a received signal to restore transmission data. The present invention relates to an orthogonal frequency division multiplex signal receiving apparatus.
[0002]
[Prior art]
As one of systems for transmitting digital signals, an orthogonal frequency division multiplexing (OFDM) system is known.
Some of the orthogonal frequency division multiplexing systems transmit data by inserting a pilot signal having a predetermined amplitude, phase and timing into a predetermined subcarrier.
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]
A receiving apparatus that is applied to the DVB-T or ISDB-T system and receives orthogonal frequency division multiplexed signals and restores transmission data using a configuration using an equalizer, first, based on the received signal data, SP The transmission path characteristic for the subcarrier that transmitted the signal is 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 reception signal data equalized corresponding to the influence of the transmission path by performing complex division on the reception signal data using the transmission path characteristic data thus obtained, and performs demapping, etc. Thus, the transmission data can be restored.
[0005]
Here, an LPF (Low Pass Filter) is usually used as a subcarrier filter that filters and interpolates data indicating transmission path characteristics in the subcarrier direction (frequency direction).
[0006]
[Problems to be solved by the invention]
In the above prior art, data indicating transmission path characteristics is filtered by LPF and interpolated in the subcarrier direction (frequency direction) to obtain transmission path characteristic data for all subcarriers.
At this time, an error may occur in the transmission path characteristic data subjected to the filtering process due to the influence of the ripple (pulsation) of the pass band and the attenuation characteristic of the stop band.
If an error occurs in the transmission path characteristic data subjected to the filtering process as described above, an error also occurs in the received signal data, and the transmission data may not be correctly restored.
[0007]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an orthogonal frequency division multiplex signal receiving apparatus capable of appropriately equalizing a received signal and restoring correct transmission data.
[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:
Received signal data indicating an orthogonal frequency division multiplexed signal in which a distributed pilot signal is inserted in a predetermined subcarrier is input, and transmission data is restored.
First Fourier transform means for Fourier transforming input received signal data;
Based on the received signal data Fourier-transformed by the first Fourier transform means, characteristic specifying means for specifying transmission line characteristics for the subcarriers that transmitted the dispersed pilot signal;
First interpolation means for interpolating transmission path characteristics for subcarriers transmitted by the distributed pilot signal specified by the characteristic specifying means in a symbol direction;
Second interpolation means for specifying transmission path characteristics for all subcarriers by interpolating transmission path characteristics interpolated in the symbol direction by the first interpolation means in subcarrier directions;
Equalization for performing equalization processing of received signal data by complex operation of received signal data Fourier-transformed by the first Fourier transform means and data indicating transmission path characteristics specified by the second interpolation means Processing means;
Demapping means for restoring transmission data from the received signal data equalized by the equalization processing means,
The second interpolation means includes
An inverse Fourier transform means for performing inverse Fourier transform on the data indicating the transmission path characteristics interpolated in the symbol direction by the first interpolation means;
Data adjusting means for adjusting data indicating transmission path characteristics by deleting a part of the data generated by the inverse Fourier transform of the inverse Fourier transform means as zero; and
Second Fourier transform means for generating data indicating transmission path characteristics for all subcarriers by Fourier transforming the data adjusted by the data adjustment means, and supplying the data to the equalization processing means ;
A delay profile creating means for creating a delay profile by performing an inverse Fourier transform on a transmission line characteristic for a subcarrier that has transmitted the distributed pilot signal identified by the characteristic identifying means;
The data adjustment means determines data to be deleted from among the data generated by the inverse Fourier transform of the inverse Fourier transform means based on the delay profile created by the delay profile creation means.
It is characterized by that.
[0009]
According to this invention, the inverse Fourier transform means performs inverse Fourier transform on the data indicating the transmission path characteristics interpolated in the symbol direction by the first interpolation means. The data adjustment unit adjusts data indicating the transmission path characteristics by deleting a part of the data generated by the inverse Fourier transform unit as zero. The second Fourier transform means performs Fourier transform on the data adjusted by the data adjustment means to generate data indicating transmission path characteristics for all subcarriers.
Thereby, it is possible to prevent an error from occurring in the data indicating the transmission path characteristics, and it is possible to appropriately correct the received signal data and restore the correct transmission data.
[0012]
For example, the data adjusting unit includes a component corresponding to a direct wave to a component corresponding to a delayed wave delayed by a guard interval section from the direct wave using the delay profile created by the delay profile creating unit. An area is specified as a data extraction area, and in the data generated by the inverse Fourier transform of the inverse Fourier transform means, only the data included in the data extraction area is extracted as valid, the other data is set to zero, and the second A part of the data generated by the inverse Fourier transform unit may be deleted by supplying to the Fourier transform unit.
[0013]
In addition, the data adjustment unit uses the delay profile created by the delay profile creation unit to identify an area including a component corresponding to the direct wave to a component corresponding to the longest multipath as a data extraction region. In the data generated by the inverse Fourier transform of the inverse Fourier transform means, only the data included in the data extraction area is extracted as valid, and the other data is set to zero and supplied to the second Fourier transform means. Accordingly, a part of the data generated by the inverse Fourier transform unit may be deleted.
[0014]
Alternatively, the data adjustment unit specifies a component having a magnitude equal to or larger than a predetermined threshold from the delay profile created by the delay profile creation unit, and the data generated by the inverse Fourier transform of the inverse Fourier transform unit In the above, only the data corresponding to the specified component is extracted as valid, and other data is set to zero and supplied to the second Fourier transform unit, so that a part of the data generated by the inverse Fourier transform unit is obtained. It may be deleted.
[0015]
An orthogonal frequency division multiplex signal receiving method according to the second aspect of the present invention includes:
A method of recovering 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 first Fourier transform step for Fourier transforming the received signal data;
A characteristic specifying step for specifying a transmission line characteristic for a subcarrier that has transmitted a distributed pilot signal, based on the received signal data Fourier-transformed in the first Fourier transform step;
A first interpolation step of interpolating the transmission path characteristics identified in the characteristic identification step in a symbol direction;
A second interpolation step for identifying the channel characteristics for all subcarriers by interpolating the channel characteristics interpolated in the symbol direction in the first interpolation step in the subcarrier direction;
Equalization processing of received signal data by complex operation of received signal data Fourier transformed in the first Fourier transform step and data indicating transmission path characteristics for all subcarriers specified in the second interpolation step Equalization processing steps for performing
A demapping step of restoring transmission data from the reception signal data equalized in the equalization processing step,
The second interpolation step includes:
An inverse Fourier transform step of performing inverse Fourier transform on the data indicating the transmission path characteristics interpolated in the symbol direction in the first interpolation step;
A data adjustment step of adjusting data indicating transmission path characteristics by deleting a part of the data generated by the inverse Fourier transform of the inverse Fourier transform step as zero, and
A Fourier transform of the data adjusted in the data adjustment step to generate data indicating transmission path characteristics for all subcarriers, a second Fourier transform step to be subjected to a complex operation of the equalization processing step ;
A delay profile creating step of creating a delay profile by performing inverse Fourier transform on the transmission path characteristics for the subcarriers that transmitted the dispersed pilot signal identified in the characteristic identifying step;
The data adjustment step determines data to be deleted among the data generated by the inverse Fourier transform of the inverse Fourier transform step based on the delay profile created by the delay profile creation step.
It is characterized by that.
[0016]
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.
The orthogonal frequency division multiplexing signal receiving apparatus 100 according to the embodiment of the present invention receives, for example, baseband received signal data obtained by detection by an orthogonal detector, and 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).
[0017]
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.
[0018]
This orthogonal frequency division multiplexed signal is known on the receiving side to a predetermined 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). An SP (Scattered Pilot) signal having an amplitude and a phase of 2 is inserted.
[0019]
In order to receive such an orthogonal frequency division multiplexed signal and restore transmission data, the orthogonal frequency division multiplexed signal receiving apparatus 100 includes an FFT (Fast Fourier Transform) circuit 10 as illustrated in FIG. An equalization processing circuit 11 and a demapper circuit 12 are provided.
[0020]
The FFT circuit 10 performs Fourier transform on the received signal data obtained by the detection by the quadrature detector, and converts the time-series data on the time axis into the frequency component data on the frequency axis. The received signal data converted into is sent to the equalization processing circuit 11.
[0021]
The equalization processing circuit 11 performs equalization processing of received signal data to compensate for received signal data deteriorated due to the influence of the transmission path, etc. As shown in FIG. 2, characteristic data calculation processing is performed. Unit 20, symbol direction interpolation processing unit 21, subcarrier direction interpolation processing unit 22, and equalization calculation processing unit 23.
[0022]
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 path specifying data indicating the characteristics of the transmission path is generated.
At this time, the characteristic data calculation processing unit 20 obtains the transmission line characteristic data indicating the transmission line characteristic for the subcarrier transmitting the SP signal by complex division, and inserts zero as the transmission line characteristic data for the other subcarriers.
[0023]
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). The symbol direction interpolation processing unit 21 sends the transmission path characteristic data interpolated in the symbol direction by the filtering process to the subcarrier direction interpolation processing unit 22.
[0024]
The subcarrier direction interpolation processing unit 22 is for interpolating transmission path characteristic data interpolated in the symbol direction (time direction) in the subcarrier direction (frequency direction) to generate transmission path characteristic data for all subcarriers. is there.
FIG. 3 is a diagram illustrating a configuration of the subcarrier direction interpolation processing unit 22.
As illustrated, the subcarrier direction interpolation processing unit 22 includes a characteristic data IFFT (Inverse FFT) processing unit 30, a characteristic data adjustment processing unit 31, and a characteristic data FFT processing unit 32. Is done.
[0025]
The characteristic data IFFT processing unit 30 performs inverse Fourier transform on the transmission line characteristic data to convert the data on the frequency axis into the data on the time axis.
[0026]
The characteristic data adjustment processing unit 31 extracts a part of the transmission line characteristic data received from the characteristic data IFFT processing part 30 and deletes the remaining data as zero, thereby adjusting the transmission line characteristic data. Is.
For example, the characteristic data adjustment processing unit 31 extracts only data in a region corresponding to one third of the number of samples from the transmission path characteristic data that has been subjected to inverse Fourier transform by the characteristic data IFFT processing unit 30 as valid, Delete the area data as zero.
[0027]
The characteristic data FFT processing unit 32 performs Fourier transform on the transmission line characteristic data adjusted by the characteristic data adjustment processing unit 31 to convert the data on the time axis into the data on the frequency axis.
[0028]
The equalization arithmetic processing unit 23 shown in FIG. 2 is configured by a numerical arithmetic circuit or the like. For example, the equalization arithmetic processing unit 23 received from the FFT circuit 10 using transmission characteristic data for all subcarriers specified by the subcarrier direction interpolation processing unit 22. The received signal data is equalized by complex division of the received signal data.
[0029]
The demapper circuit 12 shown in FIG. 1 is composed of, for example, a ROM (Read Only Memory) or the like, and restores transmission data from the received signal data equalized by the equalization processing circuit 11 based on a symbol arrangement diagram on a 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 restored.
The demapper circuit 12 outputs the restored transmission data to a deinterleave circuit or the like, and uses it for processing on the transmission data.
[0030]
The operation of orthogonal frequency division multiplex signal receiving apparatus 100 according to the embodiment of the present invention will be described below.
When the orthogonal frequency division multiplexing signal receiving apparatus 100 restores transmission data, first, the FFT circuit 10 receives the received signal data obtained by the detection of the orthogonal detector, performs Fourier transform, and converts the frequency from the time series data. Convert to component data.
The FFT circuit 10 sends the received signal data as frequency series data to the equalization processing circuit 11.
[0031]
Next, the equalization processing circuit 11 executes processing for equalizing the received signal data received from the FFT circuit 10.
FIG. 4 is a diagram showing a configuration of an orthogonal frequency division multiplexed signal indicated by received signal data input to the equalization processing circuit 11.
In FIG. 4, 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 subcarriers in the subcarrier direction (frequency direction).
[0032]
For example, the characteristic data calculation processing unit 20 generates a reference SP signal generated with a known amplitude, phase and timing on the receiving side of a subcarrier (indicated by the suffix SP in FIG. 4) that transmitted the SP signal. Complex division by. Thereby, the transmission path characteristic with respect to the subcarrier which transmitted SP signal can be calculated | required.
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.
[0033]
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.
[0034]
FIG. 5A is a diagram illustrating an example of transmission path characteristic data interpolated in the symbol direction (time direction) by the symbol direction interpolation processing unit 21.
The circles on the frequency axis in FIG. 5A indicate the frequency points where the values of the transmission line characteristic data exist.
Here, the transmission path characteristic data interpolated in the symbol direction (time direction) by the symbol direction interpolation processing unit 21 has an interval of two frequency points corresponding to two subcarriers as shown in FIG. Each open frequency point has a non-zero value.
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.
[0035]
When the subcarrier direction interpolation processing unit 22 receives the transmission path characteristic data from the symbol direction interpolation processing unit 21, the characteristic data IFFT processing unit 30 performs inverse Fourier transform on the transmission path characteristic data and sends it to the characteristic data adjustment processing unit 31. .
Thereby, the transmission path characteristic data is converted from data on the frequency axis to data on the time axis.
[0036]
FIG. 5B is a diagram illustrating an example of transmission line characteristic data converted into data on the time axis by inverse Fourier transform of the characteristic data IFFT processing unit 30.
The characteristic data IFFT processing unit 30 sends the transmission line characteristic data subjected to inverse Fourier transform to the characteristic data adjustment processing unit 31.
[0037]
The characteristic data adjustment processing unit 31 extracts a part of the transmission line characteristic data received from the characteristic data IFFT processing unit 30, and deletes the remaining data as zero.
For example, the characteristic data adjustment processing unit 31 corresponds to one third of the number of samples when the characteristic data IFFT processing unit 30 performs inverse Fourier transform on the transmission line characteristic data on the time axis shown in FIG. Only data belonging to the region A to be extracted is extracted as valid.
The characteristic data adjustment processing unit 31 deletes data belonging to the region B other than the region A as zero, and then sends the data to the characteristic data FFT processing unit 32.
[0038]
Here, among the transmission line characteristic data on the time axis shown in FIG. 5B, the data belonging to the region B includes transmission line characteristic data every two subcarriers as shown in FIG. Only harmonic components due to having non-zero (non-zero) values are included.
Therefore, the characteristic data adjustment processing unit 31 extracts only the data belonging to the region A as valid and supplies it to the characteristic data FFT processing unit 32, whereby only the low frequency component of the transmission line characteristic data can be extracted. Interpolation of characteristic data in the subcarrier direction (frequency direction) is possible.
[0039]
Thus, since the characteristic data adjustment processing unit 31 extracts only data belonging to the predetermined region A as valid, for example, unlike when filtering using an LPF (Low Pass Filter), the ripple (pulsation) of the pass band, etc. Will not be affected. Therefore, it is possible to prevent an error from occurring in the transmission path characteristic data.
[0040]
The characteristic data FFT processing unit 32 performs Fourier transform on the transmission line characteristic data received from the characteristic data adjustment processing unit 31, and converts the time-series data on the time axis into frequency component data on the frequency axis.
Thereby, for example, transmission path characteristic data interpolated in the subcarrier direction (frequency direction) as shown in FIG. 5C is generated. That is, it is possible to specify transmission path characteristic data for subcarriers marked with-in FIG. 4 and obtain transmission path characteristic data for all subcarriers.
The characteristic data FFT processing unit 32 sends the transmission path characteristic data subjected to Fourier transform to the equalization calculation processing unit 23.
[0041]
The equalization arithmetic processing unit 23 performs complex arithmetic such as complex division of the reception signal data received from the FFT circuit 10 using the transmission path characteristic data received from the characteristic data FFT processing unit 32, and receives signal data Is equalized.
The equalization arithmetic processing unit 23 sends the received signal data subjected to the equalization processing to the demapper circuit 12.
[0042]
The demapper circuit 12 restores transmission data using the received signal data subjected to equalization processing by the equalization calculation processing unit 23, and outputs it to a circuit or the like that processes the transmission data such as a deinterleave circuit.
[0043]
As described above, according to the present invention, when the transmission line characteristic data is interpolated in the subcarrier direction (frequency direction), the transmission line characteristic data is subjected to inverse Fourier transform, and only the data belonging to the predetermined region is validated. By extracting, harmonic components included in the transmission path characteristic data can be removed.
As a result, it is possible to prevent the occurrence of an error in the transmission line characteristic data as in the case of filtering using an LPF (Low Pass Filter), and it is possible to properly equalize the received signal data and restore the correct transmission data. .
[0044]
The present invention is not limited to the above embodiment, and various modifications and applications are possible.
For example, in the above-described embodiment, the characteristic data adjustment processing unit 31 extracts only the data in the region corresponding to one third of the number of samples from the transmission line characteristic data subjected to inverse Fourier transform by the characteristic data IFFT processing unit 30. Although described as extracting, it is not limited to this.
That is, for example, the characteristic data adjustment processing unit 31 may specify data to be extracted using a delay profile obtained by performing inverse Fourier transform on transmission path characteristic data for a subcarrier that transmits an SP signal. Good.
[0045]
In this case, as shown in FIG. 6, the subcarrier direction interpolation processing unit 22 includes a delay profile creation processing unit 40 for creating a delay profile from transmission path characteristic data obtained by the characteristic data calculation processing unit 20. The delay profile creation processing unit 40 creates a delay profile by performing inverse Fourier transform on the transmission path characteristic data obtained only by the characteristic data calculation processing unit 20 for the subcarrier that transmitted the SP signal, and performs characteristic data adjustment processing. To the unit 31.
[0046]
In such a configuration, for example, the characteristic data adjustment processing unit 31 uses the delay profile created by the delay profile creation processing unit 40 to identify an area corresponding to the guard interval section of the direct wave as a data extraction area. . That is, the characteristic data adjustment processing unit 31 specifies, as a data extraction region, a region including a component corresponding to a direct wave to a component corresponding to a delayed wave delayed by a guard interval section from the direct wave in the delay profile. .
The characteristic data adjustment processing unit 31 extracts the data included in the data extraction area as valid from the transmission line characteristic data received from the characteristic data IFFT processing unit 30, deletes the other data as zero, and then deletes the characteristic data FFT. You may supply to the process part 32. FIG.
[0047]
Here, the guard interval interval is a redundant signal interval that is provided between effective symbol intervals in the orthogonal frequency division multiplexing system and cyclically repeats the waveform of the effective symbol interval.
In a normal system using an orthogonal frequency division multiplexing system, a service area is constructed so that a multipath that causes a delay exceeding a guard interval section does not occur. Accordingly, the characteristic data adjustment processing unit 31 extracts only the data in the area corresponding to the guard interval section of the direct wave, so that transmission path characteristic data with less error can be obtained.
[0048]
Alternatively, the characteristic data adjustment processing unit 31 identifies the multipath component using the delay profile created by the delay profile creation processing unit 40, and the component corresponding to the delayed wave that is the longest path from the component corresponding to the direct wave It is also possible to specify an area including the above as a data extraction area and extract / delete data.
[0049]
Further, the characteristic data adjustment processing unit 31 specifies a component having a value larger than a predetermined threshold from the delay profile created by the delay profile creation processing unit 40, and transmits the transmission path characteristic received from the characteristic data IFFT processing unit 30. Of the data, only data corresponding to the specified component may be extracted as valid.
[0050]
Further, the calculation for equalizing the received signal data is not limited to the above embodiment, and can be arbitrarily changed.
For example, data obtained by complex division of a reference SP signal by a subcarrier extracted from received signal data may be used as transmission path characteristic data for a subcarrier that transmits an SP signal. This data corresponds to the reciprocal of the transmission line characteristic data in the above embodiment, and the equalization calculation processing unit 23 can equalize the received signal data by executing complex multiplication.
[0051]
【The invention's effect】
As described above, according to the present invention, when the transmission line characteristic data is interpolated in the subcarrier direction (frequency direction), the transmission line characteristic data is subjected to inverse Fourier transform, and only the data belonging to a predetermined region is effective. And performing Fourier transform with other data as zero, it is possible to prevent errors in the transmission path characteristic data.
Thereby, it is possible to properly equalize the received signal data and restore correct transmission data.
[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 circuit.
FIG. 3 is a diagram illustrating a configuration of a subcarrier direction interpolation processing unit.
FIG. 4 is a diagram illustrating a configuration of an orthogonal frequency division multiplexed signal.
FIG. 5 is a diagram for explaining an operation in which a subcarrier direction interpolation processing unit interpolates transmission path characteristic data.
FIG. 6 is a diagram showing a configuration of a subcarrier direction interpolation processing unit in 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 circuit 12 Demapper circuit 20 Characteristic data calculation process part 21 Symbol direction interpolation process part 22 Subcarrier direction interpolation process part 23 Equalization calculation process part 30 Characteristic data IFFT process part 31 Characteristic data adjustment process part 32 Characteristic Data FFT processing unit 40 Delay profile creation processing unit 100 Orthogonal frequency division multiplexing signal receiver

Claims (5)

An orthogonal frequency division multiplex signal receiving apparatus for receiving reception signal data indicating an orthogonal frequency division multiplex signal in which a distributed pilot signal is inserted in a predetermined subcarrier and restoring transmission data,
First Fourier transform means for Fourier transforming input received signal data;
Based on the received signal data Fourier-transformed by the first Fourier transform means, characteristic specifying means for specifying transmission line characteristics for the subcarriers that transmitted the dispersed pilot signal;
First interpolation means for interpolating transmission path characteristics for subcarriers transmitted by the distributed pilot signal specified by the characteristic specifying means in a symbol direction;
Second interpolation means for specifying transmission path characteristics for all subcarriers by interpolating transmission path characteristics interpolated in the symbol direction by the first interpolation means in subcarrier directions;
Equalization for performing equalization processing of received signal data by complex operation of received signal data Fourier-transformed by the first Fourier transform means and data indicating transmission path characteristics specified by the second interpolation means Processing means;
Demapping means for restoring transmission data from the received signal data equalized by the equalization processing means,
The second interpolation means includes
An inverse Fourier transform means for performing inverse Fourier transform on the data indicating the transmission path characteristics interpolated in the symbol direction by the first interpolation means;
Data adjusting means for adjusting data indicating transmission path characteristics by deleting a part of the data generated by the inverse Fourier transform of the inverse Fourier transform means as zero; and
Second Fourier transform means for generating data indicating transmission path characteristics for all subcarriers by Fourier transforming the data adjusted by the data adjustment means, and supplying the data to the equalization processing means ;
A delay profile creating means for creating a delay profile by performing an inverse Fourier transform on a transmission line characteristic for a subcarrier that has transmitted the distributed pilot signal identified by the characteristic identifying means;
The data adjustment means determines data to be deleted from among the data generated by the inverse Fourier transform of the inverse Fourier transform means based on the delay profile created by the delay profile creation means.
An orthogonal frequency division multiplex signal receiving apparatus. The data adjustment means uses the delay profile created by the delay profile creation means to include an area from a component corresponding to a direct wave to a component corresponding to a delayed wave delayed by a guard interval section from the direct wave. In the data generated by the inverse Fourier transform of the inverse Fourier transform means, the data is identified as a data extraction region, and only the data included in the data extraction region is extracted as valid, the other data is set to zero, and the second Fourier Deleting a part of the data generated by the inverse Fourier transform means by supplying to the transform means;
The orthogonal frequency division multiplex signal receiver according to claim 1 . The data adjustment means uses the delay profile created by the delay profile creation means to identify, as a data extraction area, an area including a component corresponding to the direct wave to a component corresponding to the delayed wave that is the longest path In the data generated by the inverse Fourier transform of the inverse Fourier transform means, only the data included in the data extraction area is extracted as valid, and the other data is set to zero and supplied to the second Fourier transform means. By deleting a part of the data generated by the inverse Fourier transform means,
The orthogonal frequency division multiplex signal receiver according to claim 1 . The data adjusting means specifies a component having a magnitude greater than a predetermined threshold from the delay profile created by the delay profile creating means, and in the data generated by the inverse Fourier transform of the inverse Fourier transform means, Only data corresponding to the specified component is extracted as valid, and other data is set to zero and supplied to the second Fourier transform unit, thereby deleting a part of the data generated by the inverse Fourier transform unit. ,
The orthogonal frequency division multiplex signal receiver according to claim 1 . An orthogonal frequency division multiplexing signal receiving method for restoring transmission data from reception signal data indicating an orthogonal frequency division multiplexing signal in which a distributed pilot signal is inserted in a predetermined subcarrier,
A first Fourier transform step for Fourier transforming the received signal data;
A characteristic specifying step for specifying a transmission line characteristic for a subcarrier that has transmitted a distributed pilot signal, based on the received signal data Fourier-transformed in the first Fourier transform step;
A first interpolation step of interpolating the transmission path characteristics identified in the characteristic identification step in a symbol direction;
A second interpolation step for identifying the channel characteristics for all subcarriers by interpolating the channel characteristics interpolated in the symbol direction in the first interpolation step in the subcarrier direction;
Equalization processing of received signal data by complex operation of received signal data Fourier transformed in the first Fourier transform step and data indicating transmission path characteristics for all subcarriers specified in the second interpolation step Equalization processing steps for performing
A demapping step of restoring transmission data from the reception signal data equalized in the equalization processing step,
The second interpolation step includes:
An inverse Fourier transform step of performing inverse Fourier transform on the data indicating the transmission path characteristics interpolated in the symbol direction in the first interpolation step;
A data adjustment step of adjusting data indicating transmission path characteristics by deleting a part of the data generated by the inverse Fourier transform of the inverse Fourier transform step as zero, and
A Fourier transform of the data adjusted in the data adjustment step to generate data indicating transmission path characteristics for all subcarriers, a second Fourier transform step to be subjected to a complex operation of the equalization processing step ;
A delay profile creating step of creating a delay profile by performing inverse Fourier transform on the transmission path characteristics for the subcarriers that transmitted the dispersed pilot signal identified in the characteristic identifying step;
The data adjustment step determines data to be deleted among the data generated by the inverse Fourier transform of the inverse Fourier transform step based on the delay profile created by the delay profile creation step.
An orthogonal frequency division multiplex signal receiving method.

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