JP5023006B2 - OFDM signal receiving apparatus and relay apparatus - Google Patents

Description

  The present invention relates to an OFDM signal receiving apparatus and a relay apparatus that perform digital broadcasting or digital transmission using an OFDM (Orthogonal Frequency Division Multiplexing) system, and in particular, when receiving radio waves in digital broadcasting, wireless LAN, and the like. In particular, the present invention relates to an OFDM signal receiving apparatus and a relay apparatus that correctly receive transmission data in an environment for receiving such a multipath even when the delay time of the multipath exceeds a GI (Guard Interval) length.

  FIG. 8 is a block diagram showing a configuration of a conventional OFDM signal receiving apparatus. The OFDM signal receiving apparatus 100 is an ordinary apparatus that is generally used, and includes a frequency conversion unit 10, an A / D conversion unit 11, an orthogonal demodulation unit 12, an FFT (Fast Fourier Transform) unit 13, a channel estimation unit 40, A channel equalization unit 41, a demapping unit 19, and a P / S (parallel serial) conversion unit 20 are provided.

  According to the OFDM signal receiving apparatus 100, channel equalization can be normally performed when the multipath delay time indicating the delay spread of the transmission path from the transmission source to the reception point is within the GI length. On the other hand, when the multipath delay time exceeds the GI length, inter-symbol interference and inter-carrier interference occur, and reception characteristics are significantly impaired. Therefore, channel equalization cannot be performed normally.

  FIG. 9 is a block diagram showing another configuration of the conventional OFDM signal receiving apparatus. This OFDM signal receiving apparatus 101 is an apparatus capable of normal channel equalization even when the multipath delay time exceeds the GI length. The OFDM signal receiving apparatus 101 includes a frequency conversion unit 10, an A / D conversion unit 11, an orthogonal demodulation unit 12, a subtraction unit 42, an adaptive filter unit 43, an FFT unit 44, a channel estimation unit 40, a channel equalization unit 41, a demapping Unit 19, P / S conversion unit 20, remapping unit 45, division unit 46, and filter coefficient control unit 47.

  The division unit 46 divides the signal before channel equalization FFT by the FFT unit 44 by the signal after channel equalization processed by the channel equalization unit 41, the demapping unit 19 and the remapping unit 45. Then, the filter coefficient control unit 47 calculates a filter coefficient from the division result and outputs it to the adaptive filter unit 43. That is, the adaptive filter unit 43 can input the impulse response excluding the main wave component from the channel response from the transmission source to the reception point as a filter coefficient, so that the subtraction unit 42 can cancel the multipath. is there.

  By the way, the OFDM signal receiving apparatus 101 shown in FIG. 9 can cancel multipath in the time domain. In contrast, Patent Document 1 discloses an OFDM signal receiving apparatus capable of equalizing multipaths in the frequency domain.

JP 2004-343546 A

  However, the conventional OFDM signal receiving apparatus 101 shown in FIG. 9 has a problem that it is necessary to increase the order of the adaptive filter unit 43 in order to cancel a multipath having a longer delay time in the subtracting unit 42. . Further, in order to equalize a multipath (preceding wave) that arrives earlier than the main wave, there is a problem in that an adaptive filter needs to be added in addition to the configuration shown in FIG. Therefore, a multipath having a longer delay time can be equalized without increasing the order of the adaptive filter unit 43, and a multipath that arrives earlier than the main wave can be detected without adding an adaptive filter. An OFDM signal receiving apparatus capable of equalization has been desired.

  As described above, when the multipath delay time exceeds the GI length, the normal OFDM signal receiving apparatus 100 shown in FIG. 8 cannot perform channel equalization normally, but it is shown in FIG. The conventional OFDM signal receiving apparatus 101 and the OFDM signal receiving apparatus disclosed in Patent Document 1 can perform channel equalization normally.

  On the other hand, in an environment where a multipath having a large amplitude such that the delay time of the multipath is within the GI length and the D / U (Desireed to Undesired ratio) is close to 0 dB is received as shown in FIG. The OFDM signal receiving apparatus 100 can perform channel equalization normally.

  However, the OFDM signal receiving apparatus of Patent Document 1 performs equalization at a frequency interval narrower than the subcarrier interval of the OFDM signal in the frequency domain. As a result, the noise component of the subcarrier frequency where C / N (Carrier to Noise Ratio) is significantly deteriorated is raised to the signal level. Then, by reconstructing such a signal, peripheral subcarriers that have not deteriorated so much are affected, and their C / N deteriorates.

  That is, in an environment for receiving a multipath with a large amplitude such that the multipath delay time is within the GI length and the D / U is close to 0 dB, the normal OFDM signal receiving apparatus 100 shown in FIG. Then, although channel equalization can be performed normally, the OFDM signal receiving apparatus disclosed in Patent Document 1 has a problem that channel equalization cannot be performed normally and reception becomes impossible.

  Therefore, the present invention has been made to solve such a problem, and its purpose is to provide an amplitude such that the D / U is close to 0 dB when the multipath delay time is within the GI length. Even in an environment where a large multipath is received, the channel equalization is normally performed by having reception characteristics similar to those of a normal OFDM signal receiver, and when the multipath delay time exceeds the GI length, It is an object of the present invention to provide an OFDM signal receiving apparatus capable of normally performing channel equalization and a relay apparatus that relays a higher-order local wave favorably and stably using the OFDM signal receiving apparatus.

  In order to achieve the above object, an OFDM signal receiving apparatus according to claim 1 according to the present invention is an OFDM signal receiving apparatus that receives and demodulates an OFDM signal and outputs a bit string signal, from a transmission source to a reception point. A channel response at a frequency interval that is a power of 2 with respect to the carrier interval of the OFDM signal, a channel estimation unit that outputs the channel response, an equivalent baseband signal after orthogonal demodulation, Based on the FFT unit that outputs the frequency domain signal by performing FFT with the number of samples that is a power of 2 with respect to the effective symbol length, the frequency domain signal output by the FFT unit, and the channel response output by the channel estimation unit, A replica generation unit that generates a multipath replica included in the OFDM signal and outputs the multipath replica; and IFFT unit that performs multipath replica time domain signal by performing IFFT (Inverse Fast Fourier Transform) on the multipath replica output from the Rica generating unit with the number of samples that is a power of 2 with respect to the effective symbol length of the OFDM signal And a subtractor for subtracting the time domain signal of the multipath replica output from the IFFT unit from the equivalent baseband signal after quadrature demodulation and outputting the equivalent baseband signal after multipath cancellation. The equivalent baseband signal after multipath cancellation output from the subtracting unit is subjected to FFT to equalize the channel and output the bit string signal.

  An OFDM signal receiving apparatus according to claim 2 according to the present invention is an OFDM signal receiving apparatus that receives and demodulates an OFDM signal and outputs a bit string signal, wherein the carrier of the OFDM signal from a transmission source to a reception point is provided. A channel response is calculated at a frequency interval that is a power of 2 with respect to the interval, and a channel estimation unit that outputs the channel response, and an equivalent baseband signal after orthogonal demodulation are calculated with respect to an effective symbol length of the OFDM signal Based on the first FFT unit that outputs the frequency domain signal, the frequency domain signal output by the first FFT unit, and the channel response output by the channel estimation unit. Generating a multipath replica included in the OFDM signal and outputting the multipath replica; and the replica The IFFT unit that outputs the multi-path replica time domain signal by performing IFFT on the multi-path replica output by the generator with a number of samples that is a power of 2 with respect to the effective symbol length of the OFDM signal; FFT of the equivalent baseband signal to output a carrier symbol, and a second FFT unit to output a carrier symbol, and a third path to output the multipath replica carrier symbol by FFT of the time domain signal of the multipath replica output from the IFFT unit. A subtracting unit that subtracts the carrier symbol of the multipath replica output from the third FFT unit from the carrier symbol output from the FFT unit and the second FFT unit, and outputs the carrier symbol after multipath cancellation; The carrier symbol after multipath cancellation output from the subtraction unit is channel-equalized. And outputs the bit sequence signal.

  The OFDM signal receiving apparatus according to claim 3 of the present invention is the OFDM signal receiving apparatus according to claim 1 or 2, wherein the channel estimation unit performs channel estimation based on a pilot signal and outputs a channel response. A carrier symbol obtained by FFT of the first channel estimation unit and the equivalent baseband signal after multipath cancellation in claim 1 or a carrier symbol after multipath cancellation output from the subtraction unit in claim 2 A channel equalization unit that performs channel equalization by dividing by a channel response output by the first channel estimation unit and outputs a carrier symbol after channel equalization; A carrier symbol obtained by performing FFT on an equivalent baseband signal, or claim 2 Second channel estimation for performing channel estimation and outputting a channel response based on the carrier symbol after multipath cancellation output from the subtraction unit and the carrier symbol after channel equalization output from the channel equalization unit. And a multipath D that detects a minimum multipath D / U value with a delay time within the GI length and outputs a multipath D / U minimum value from the channel response output from the first channel estimation unit / U detector, the channel response output from the second channel estimator, and the multipath D / U minimum value output from the multipath D / U detector. A third channel estimator that calculates a channel response at a frequency interval of a power of two and outputs the channel response. To.

  An OFDM signal receiving apparatus according to a fourth aspect of the present invention is the OFDM signal receiving apparatus according to the third aspect, wherein the third channel estimation unit is based on a channel response output from the second channel estimation unit. A main wave detection unit that detects a wave component and outputs the main wave component; and subtracts the main wave component output from the main wave detection unit from a channel response output from the second channel estimation unit; An adaptive coefficient is set from the subtractor that outputs the multipath component and the multipath D / U minimum value output from the multipath D / U detector, and the adaptive coefficient is set to output the adaptive coefficient The multipath component output from the subtractor, the multipath component output from the adaptive coefficient setting unit, and the multipath component output from the adaptive coefficient setting unit. Person in charge Add the main wave component output from the main wave detection unit to the multipath component after multiplication, and output the channel response after addition, and the channel response after addition output from the addition unit as 2 An interpolator that interpolates to a power multiple and outputs a channel response after the interpolation, and a channel response after a predetermined unit update time is multiplied by the channel response after the interpolation output by the interpolator, and a channel response is output. And a delay unit that holds a channel response output from the multiplier for the unit update time and outputs a channel response before the unit update time.

  Also, in the OFDM signal receiving apparatus according to claim 5 of the present invention, the first channel estimator comprises the carrier symbol obtained by performing FFT on the equivalent baseband signal after multipath cancellation in claim 1, or The pilot symbol is extracted from the carrier symbol after multipath cancellation output from the subtracting unit in step 2, the pilot extracting unit outputting the pilot symbol, the pilot generating unit generating and outputting the pilot signal, and the pilot extracting unit Is divided by a pilot signal output from the pilot generation unit to obtain a channel response, and a channel unit that outputs the channel response is divided into a symbol direction and a subcarrier. Interpolate in the direction and An interpolation unit for calculating a channel response, and the second channel estimation unit reproduces a symbol by demapping and remapping the channel equalized carrier symbol output from the channel equalization unit. A symbol reproduction unit that outputs a reproduction symbol, a carrier symbol obtained by performing FFT on the equivalent baseband signal after multipath cancellation in claim 1, or a multipath cancellation after output from the subtraction unit in claim 2 A division unit that divides a carrier symbol by a reproduction symbol output from the symbol reproduction unit and outputs a channel response, and the multipath D / U detection unit outputs the first channel estimation unit IFFT channel response to time domain signal delay profile and output the delay profile A main wave detection unit that detects a sample having the maximum amplitude among all samples of the delay profile output from the IFFT unit, and outputs the sample time and amplitude of the main wave component using the sample as the main wave component; The sample time of the main wave component output from the main wave detector is set as a reference time, and the sample time range in which the absolute value of the time difference from the reference time is within the GI length is set. Detection range setting unit that outputs the detection range, and the delay profile output from the IFFT unit has a maximum amplitude except for the sample of the main wave component among the samples in the detection range output by the detection range setting unit. A maximum value detection unit that outputs a multipath component amplitude using the sample as a multipath component, and outputs the main wave detection unit And a division unit that divides the amplitude of the main wave component by the amplitude of the multipath component output from the maximum value detection unit and outputs a multipath D / U minimum value.

  A relay apparatus according to a sixth aspect of the present invention uses the OFDM signal receiving apparatus according to any one of the first to fifth aspects.

  As described above, according to the present invention, when the multipath delay time is within the GI length, even in an environment where a multipath with a large amplitude such that the D / U is close to 0 dB is received, Channel equalization can be performed normally. Also, even when the multipath delay time exceeds the GI length, channel equalization can be performed normally.

The best mode for carrying out the present invention will be described below in detail with reference to the drawings.
[Example 1]
First, Example 1 will be described. FIG. 1 is a block diagram showing a first configuration of an OFDM signal receiving apparatus according to an embodiment of the present invention. The OFDM signal receiving apparatus 1 includes a frequency conversion unit 10, an A / D conversion unit 11, an orthogonal demodulation unit 12, a first FFT unit 13, a replica generation unit 14, an IFFT unit 15, a subtraction unit 16, and a second FFT unit. 17, a channel estimation unit 18, a demapping unit 19, and a P / S conversion unit 20. The channel estimation unit 18 includes a first channel estimation unit 21, a channel equalization unit 22, a multipath D / U detection unit 23, a second channel estimation unit 24, and a third channel estimation unit 25. .

  The frequency conversion unit 10 receives a received signal that is an OFDM signal received by the OFDM signal receiving apparatus 1, performs frequency conversion on the received signal, and outputs an IF signal. The IF signal output from the frequency converter 10 is input to the A / D converter 11. The A / D converter 11 receives the IF signal from the frequency converter 10, A / D converts the IF signal (analog IF signal), and outputs a digital IF signal. The digital IF signal output from the A / D converter 11 is input to the quadrature demodulator 12. The quadrature demodulator 12 receives the digital IF signal from the A / D converter 11, performs quadrature demodulation on the digital IF signal, and outputs an equivalent baseband signal. The equivalent baseband signal output from the quadrature demodulator 12 is divided into two, one being input to the subtractor 16 and the other being input to the first FFT unit 13.

  The first FFT unit 13 receives the equivalent baseband signal from the quadrature demodulation unit 12, and performs FFT on the equivalent baseband signal with the number of points (number of samples) that is a power of 2 with respect to the effective symbol length of the OFDM signal. , Output frequency domain signal. The frequency domain signal output from the first FFT unit 13 is input to the replica generation unit 14.

  The replica generation unit 14 receives the frequency domain signal from the first FFT unit 13 and also receives the channel response (channel response from the transmission source to the reception point) from the channel estimation unit 18 to obtain the frequency domain signal and the channel response. Based on this, a multipath replica (hereinafter referred to as “multipath replica frequency domain signal”) is generated. The frequency domain signal of the multipath replica output from the replica generation unit 14 is input to the IFFT unit 15.

  The IFFT unit 15 receives the frequency domain signal of the multipath replica from the replica generation unit 14, performs an IFFT on the frequency domain signal of the multipath replica, and outputs a time domain signal of the multipath replica. The time domain signal of the multipath replica output from the IFFT unit 15 is input to the subtracting unit 16.

  The subtracting unit 16 receives the equivalent baseband signal from the quadrature demodulating unit 12 and also receives the time domain signal of the multipath replica from the IFFT unit 15 and subtracts the time domain signal of the multipath replica from the equivalent baseband signal. Cancel the multipath component and output the equivalent baseband signal after multipath cancellation. The equivalent baseband signal after multipath cancellation output from the subtraction unit 16 is input to the second FFT unit 17.

  The second FFT unit 17 inputs the equivalent baseband signal after multipath cancellation from the subtraction unit 16, and performs FFT on the equivalent baseband signal after multipath cancellation by the number of points corresponding to the effective symbol length of the OFDM signal. The carrier symbol is output. The carrier symbol output from the second FFT unit 17 is input to the channel estimation unit 18.

  The channel estimation unit 18 receives the carrier symbol from the FFT unit 17, estimates the channel response from the transmission source to the reception point, outputs the channel response to the replica generation unit 14, performs channel equalization, and performs channel equalization. The subsequent carrier symbol is output to the demapping unit 19. Details of the channel estimation unit 18 will be described later.

  The demapping unit 19 receives the carrier symbol after channel equalization from the channel estimation unit 18, demaps the carrier symbol after channel equalization, converts it into a parallel signal, and outputs it. The parallel signal output from the demapping unit 19 is output to the P / S conversion unit 20. The P / S conversion unit 20 receives the parallel signal from the demapping unit 19, performs parallel-serial conversion on the parallel signal, and outputs an output bit string signal to the outside.

[Channel estimation section]
Next, the channel estimation unit 18 will be described in detail. The carrier symbols output from the second FFT unit 17 are divided into three and input to the channel equalization unit 22, the first channel estimation unit 21, and the second channel estimation unit 24, respectively.

  The first channel estimation unit 21 receives the carrier symbol from the second FFT unit 17, extracts the pilot signal, calculates the channel response, and outputs the first channel response. The first channel response output from the first channel estimation unit 21 is divided into two, one being input to the channel equalization unit 22 and the other being input to the multipath D / U detection unit 23.

  FIG. 3 is a block diagram illustrating a configuration of the first channel estimation unit 21 in the channel estimation unit 18 illustrated in FIG. 1. The first channel estimation unit 21 includes a pilot extraction unit 211, a pilot generation unit 212, a division unit 213, and an interpolation unit 214. The pilot extraction unit 211 receives a carrier symbol from the second FFT unit 17, extracts a pilot symbol from the carrier symbol, and outputs the pilot symbol. Pilot symbols output from pilot extraction section 211 are input to division section 213.

  Pilot generating section 212 generates and outputs a pilot signal having a predetermined amplitude and phase. The pilot signal output from pilot generator 212 is input to divider 213. Division section 213 receives the pilot symbol from pilot extraction section 211 and also receives the pilot signal from pilot generation section 212, divides the pilot symbol by the pilot signal, and outputs a channel response. The channel response output from the division unit 213 is input to the interpolation unit 214.

  The interpolation unit 214 receives the channel response from the division unit 213, interpolates the channel response in the symbol direction and the subcarrier direction, calculates the channel response in all subcarrier frequencies of the OFDM signal, and outputs the first channel response To do. The first channel response output from the interpolation unit 214 is divided into two, one being input to the channel equalization unit 22 and the other being input to the multipath D / U detection unit 23.

  Returning to FIG. 1, the channel equalization unit 22 receives the carrier symbol from the second FFT unit 17 and also receives the first channel response from the first channel estimation unit 21, and converts the carrier symbol into the first symbol. Channel equalization is performed by dividing by the channel response, and the carrier symbol after channel equalization is output. The carrier symbols after channel equalization by the channel equalization unit 22 are divided into two, one being input to the demapping unit 19 and the other being input to the second channel estimation unit 24.

  The second channel estimation unit 24 receives a carrier symbol from the second FFT unit 17 and also receives a carrier symbol after channel equalization from the channel equalization unit 22, and transmits a transmission symbol from the carrier symbol after channel equalization. Is reproduced, and the channel response is calculated by dividing the carrier symbol after channel equalization by the reproduced symbol, and the second channel response is output. The second channel response output from the second channel estimation unit 24 is input to the third channel estimation unit 25.

  FIG. 4 is a block diagram showing a configuration of the second channel estimation unit 24 in the channel estimation unit 18 shown in FIG. The second channel estimation unit 24 includes a symbol reproduction unit 241 and a division unit 242. The symbol reproducing unit 241 receives the channel equalized carrier symbol from the channel equalizing unit 22, demaps and remaps the channel equalized carrier symbol, reproduces the carrier symbol, and outputs the reproduced symbol. The reproduction symbol output from the symbol reproduction unit 241 is input to the division unit 242.

  The division unit 242 receives the carrier symbol from the second FFT unit 17 and also receives the reproduction symbol from the symbol reproduction unit 241, divides the carrier symbol by the reproduction symbol, and outputs a second channel response. The second channel response output from the division unit 242 is input to the third channel estimation unit 25.

  Returning to FIG. 1, the multipath D / U detection unit 23 receives the first channel response from the first channel estimation unit 21, and within the time range of the GI length based on the main wave on the delay profile. The multipath is specified, the D / U is calculated from the main wave amplitude and the multipath amplitude, and the multipath D / U is output. The multipath D / U output from the multipath D / U detection unit 23 is input to the third channel estimation unit 25.

  FIG. 5 is a block diagram showing a configuration of the multipath D / U detection unit 23 in the channel estimation unit 18 shown in FIG. The multipath D / U detection unit 23 includes an IFFT unit 231, a main wave detection unit 232, a detection range setting unit 233, a maximum value detection unit 234, and a division unit 235. The IFFT unit 231 receives the first channel response from the first channel estimation unit 21, converts it into a delay profile that is a time domain signal, and outputs a delay profile. The delay profile output from the IFFT unit 231 is divided into two, one being input to the main wave detection unit 232 and the other being input to the maximum value detection unit 234.

  The main wave detection unit 232 receives the delay profile from the IFFT unit 231, detects a sample having the maximum amplitude among all the samples of the delay profile, uses the sample as the main wave component, and the sample time of the main wave component and The amplitude is specified, and the sample time and amplitude of the main wave component are output. The sampling time of the main wave component output from the main wave detection unit 232 is input to the detection range setting unit 233. The amplitude of the main wave component output from the main wave detection unit 232 is input to the division unit 235.

  The detection range setting unit 233 inputs the sample time of the main wave component from the main wave detection unit 232, uses the sample time of the main wave component as a reference time, and the absolute value of the time difference from the reference time is within the GI length. A certain sample time range is set, and the sample time range (detection range) is output. The detection range output from the detection range setting unit 233 is input to the maximum value detection unit 234.

  The maximum value detection unit 234 receives the delay profile from the IFFT unit 231 and the detection range from the detection range setting unit 233, and the amplitude is maximum except for the sample of the main wave component among the samples in the detection range. Is detected, the maximum amplitude of the multipath component is specified as the multipath component, and the maximum amplitude of the multipath component in the time range of the GI length with the main wave component as a reference is output. The maximum amplitude of the multipath component output from the maximum value detection unit 234 is input to the division unit 235.

  The division unit 235 receives the amplitude of the main wave component from the main wave detection unit 232 and also receives the maximum amplitude of the multipath component from the maximum value detection unit 234, and converts the amplitude of the main wave component to the maximum amplitude of the multipath component. Divide and output the multipath D / U (minimum D / U) within the time range of the GI length based on the main wave component. The multipath D / U (minimum D / U) output from the division unit 235 is input to the third channel estimation unit 25.

  Returning to FIG. 1, the third channel estimator 25 receives the second channel response from the second channel estimator 24 and also receives the multipath D / U from the multipath D / U detector 23. The multipath component is subtracted from the second channel response to extract the multipath component, and the multipath distortion is reduced with respect to the multipath component by multiplying the adaptive coefficient set using the multipath D / U. . Then, a multipath component with reduced multipath distortion is added to the main wave component detected from the second channel response and interpolated to output a third channel response. The third channel response output from the third channel estimation unit 25 is input to the replica generation unit 14.

  FIG. 6 is a block diagram showing a configuration of the third channel estimation unit 25 in the channel estimation unit 18 shown in FIG. The third channel estimation unit 25 includes a main wave detection unit 251, a subtraction unit 252, a multiplication unit 253, an addition unit 254, an interpolator 255, a multiplication unit 256, a delay unit 257, and an adaptive coefficient setting unit 258. The main wave detection unit 251 receives the second channel response from the second channel estimation unit 24, calculates the average of the second channel response, and outputs the average channel response as the main wave component. The main wave component output from the main wave detection unit 251 is divided into two, one being input to the subtraction unit 252 and the other being input to the addition unit 254.

  The subtractor 252 receives the second channel response from the second channel estimator 24, receives the main wave component from the main wave detector 251 and subtracts the main wave component from the second channel response, Output the path component. The multipath component output from the subtraction unit 252 is input to the multiplication unit 253.

  As described above, according to the subtracting unit 252, the main wave component is removed from the second channel response, so that only the multipath component can be extracted. The multipath component may include a multipath whose delay time is within the GI length and a multipath whose delay time exceeds the GI length.

  The adaptive coefficient setting unit 258 inputs the multipath D / U (minimum D / U) within the time range of the GI length with reference to the main wave component from the multipath D / U detection unit 23, and multipath D / U An adaptive coefficient is set from U (minimum D / U) and output. The adaptation coefficient output from the adaptation coefficient setting unit 258 is input to the multiplication unit 253.

  Multiplier 253 receives the multipath component from subtractor 252 and the adaptive coefficient from adaptive coefficient setting unit 258, multiplies the multipath component by the adaptive coefficient, and has a GI length time based on the main wave component. Multipath distortion within the range is reduced, and a multipath component with reduced multipath distortion is output. The multipath component in which the multipath distortion output from the multiplier 253 is reduced is input to the adder 254.

  As described above, according to the multiplication unit 253, since the multipath component is multiplied by the adaptive coefficient, the multipath distortion within the time range of the GI length based on the main wave component is reduced with respect to the multipath component. Reduce.

  The adder 254 inputs the multipath component in which the multipath distortion is reduced within the time range of the GI length based on the main wave component from the multiplier 253, and inputs the main wave component from the subtractor 252. The main wave component is added to the multipath component, and the channel response is output. The channel response output from the adder 254 is input to the interpolator 255.

  As described above, according to the adding unit 254, the main wave component is added to the multipath component in which the multipath distortion is reduced within the time range of the GI length with respect to the main wave component. As a result, a channel response including a main wave component and a multipath component with reduced distortion can be generated.

  The interpolator 255 receives the channel response with reduced multipath distortion from the adder 254, upsamples the channel response to a power of 2, and removes the imaging component for output. The channel response output from the interpolator 255 is input to the multiplication unit 256.

  Thus, according to the interpolator 255, the channel response is upsampled to a power of two. As a result, the number of signals by the interpolator 255 can be made to correspond to the number of signals to be subjected to FFT with the number of points that is a power of 2 in the first FFT unit 13. Therefore, the replica generation unit 14 uses the frequency domain signal from the first FFT unit 13 and the third channel response from the third channel estimation unit 25 including the interpolator 255 corresponding to the number of signals. A frequency domain signal of a multipath replica can be generated.

  Multiplier 256 receives the interpolated channel response from interpolator 255 and inputs the channel response before the unit coefficient update time from delay unit 257, and the channel response interpolated to the channel response before the unit coefficient update time. Multiply the response and output a third channel response. The third channel response output from the multiplier 256 is divided into two, one input to the replica generator 14 and the other input to the delay unit 257.

  The delay unit 257 receives the third channel response from the multiplication unit 256, holds the third channel response for a preset unit coefficient update time, and delays the unit coefficient update time, that is, the unit coefficient Output the channel response before the update time. The channel response before the unit coefficient update time output from the delay unit 257 is input to the multiplication unit 256.

  As described above, according to the OFDM signal receiving apparatus 1 of the first embodiment, the channel estimation unit 18 generates a channel response including the main wave component and the multipath component with reduced distortion. Then, the replica generation unit 14 generates a frequency domain signal of the multipath replica using this channel response, and the subtraction unit 16 subtracts the time domain signal of the multipath replica from the equivalent baseband signal of the received signal. The path component was canceled. In this case, when the multipath delay time exceeds the GI length, the multipath component can be canceled by the subtracting unit 16, and the channel equalization unit 22 can normally perform channel equalization.

  On the other hand, conventionally, in the case of a multipath having a large amplitude such that the delay time of the multipath is within the GI length and the D / U is close to 0 dB, the subcarrier interval of the OFDM signal is larger in the frequency domain. Since the equalization is performed at a narrow frequency interval, the noise component of the subcarrier frequency with significantly deteriorated C / N is raised to the signal level, and the C / N of the peripheral subcarrier that has not deteriorated so much deteriorates. As a result, channel equalization cannot be normally performed. In the OFDM signal receiving apparatus 1 according to the first embodiment, the first FFT unit 13 performs FFT on the equivalent baseband signal by the number of points that is a power of 2, and the interpolator 255 of the third channel estimation unit 25 receives the input channel. The response was upsampled to a power of 2 to remove the imaging component. Then, the replica generation unit 14 inputs the frequency domain signal subjected to FFT by increasing the number of points from the FFT unit 13, and corresponds to the number of points from the third channel estimation unit 25 including the interpolator 255. A third channel response including a multipath component with reduced distortion is input to generate a frequency domain signal of the multipath replica. Accordingly, even in the case of a multipath having a large amplitude such that the multipath delay time is within the GI length and the D / U is close to 0 dB, the normal OFDM signal receiving apparatus shown in FIG. Can have the same reception characteristics as That is, the channel equalization unit 22 can perform channel equalization normally.

[Example 2]
Next, Example 2 will be described. FIG. 2 is a block diagram showing a second configuration of the OFDM signal receiving apparatus according to the embodiment of the present invention. This OFDM signal receiving apparatus 2 includes a frequency conversion unit 10, an A / D conversion unit 11, an orthogonal demodulation unit 12, a first FFT unit 13, a replica generation unit 14, an IFFT unit 15, a second FFT unit 30, a third FFT section 32, subtraction section 33, channel estimation section 18, demapping section 19 and P / S conversion section 20 are provided. The channel estimation unit 18 includes a first channel estimation unit 21, a channel equalization unit 22, a multipath D / U detection unit 23, a second channel estimation unit 24, and a third channel estimation unit 25. .

  Comparing the OFDM signal receiving apparatus 1 of the first embodiment shown in FIG. 1 and the OFDM signal receiving apparatus 2 of the second embodiment shown in FIG. 2, the OFDM signal receiving apparatus 2 of the second embodiment is similar to the OFDM signal receiving apparatus 2 of the first embodiment. The difference is that an FFT unit 30, an FFT unit 32, and a subtracting unit 33 are provided instead of the subtracting unit 16 and the FFT unit 17 in the signal receiving apparatus 1. In the OFDM signal receiving apparatus 2 shown in FIG. 2, the same reference numerals as those in FIG. 1 are given to portions common to the OFDM signal receiving apparatus 1 shown in FIG. 1, and detailed description thereof is omitted.

  In FIG. 2, the second FFT unit 30 receives the equivalent baseband signal from the quadrature demodulation unit 12, performs FFT on the equivalent baseband signal with the number of points corresponding to the effective symbol length of the OFDM signal, and performs the equivalent baseband signal. Output the carrier symbol of the signal. The carrier symbol of the equivalent baseband signal output from the second FFT unit 30 is input to the subtracting unit 16.

  The third FFT unit 32 receives the time domain signal of the multipath replica from the IFFT unit 15 and performs FFT on the time domain signal of the multipath replica with the number of points corresponding to the effective symbol length of the OFDM signal. The carrier symbol of the path replica is output. The carrier symbol of the multipath replica output from the third FFT unit 32 is input to the subtraction unit 16.

  The subtracting unit 33 inputs the carrier symbol of the equivalent baseband signal from the second FFT unit 30 and also receives the carrier symbol of the multipath replica from the third FFT unit 32, and multiplies from the carrier symbol of the equivalent baseband signal. The multipath component is canceled by subtracting the carrier symbol of the path replica, and the carrier symbol after the multipath cancellation is output. The carrier symbol after multipath cancellation output from the subtraction unit 33 is input to the channel estimation unit 18.

  As described above, according to the OFDM signal receiving apparatus 2 of the second embodiment, the same effects as those of the OFDM signal receiving apparatus 1 of the first embodiment described above can be obtained. That is, when the multipath delay time exceeds the GI length, the multipath component can be canceled by the subtracting unit 16, and the channel equalization unit 22 can normally perform channel equalization. Even in the case of a multipath with a large amplitude such that the delay time of the multipath is within the GI length and the D / U is close to 0 dB, the normal OFDM signal receiving apparatus shown in FIG. It can have the same reception characteristics, can cancel the multipath component, and can perform channel equalization normally by the channel equalization unit 22.

[When using ISDB-T (Integrated Services Digital Broadcasting-Terrestrial)]
The case where the ISDB-T system is used in the OFDM signal receiving apparatuses 1 and 2 configured as described above will be described in detail.

ここで、ｍｏｄは剰余を示す。以下、式（１）を満足するｉ，ｋをそれぞれｉ_ｐ，ｋ_ｐとする。 [First channel estimation unit]
First, the first channel estimation unit 21 will be described. In the ISDB-T system, subcarriers assigned to SP (Scattered Pilot) satisfy the following formula (1), where i is the symbol number and k is the subcarrier number.

Here, mod indicates a remainder. Hereinafter, i and k satisfying the expression (1) are assumed to be i _p and k _p , respectively.

The received SP signal extracted by the pilot extraction unit 211 of the first channel estimation unit 21 is x _{ip, kp} and is an SP signal generated by the pilot generation unit 212 (hereinafter referred to as “transmission SP signal”), that is, Assuming that the SP signal generated and transmitted in the ISDB-T modulator is s _{ip, kp} , the channel response u _{ip, kp at} the symbol number i _p and the subcarrier number k _p is expressed by equation (2).

  Here, the method of using the SP signal adopted in the ISDB-T system as the reference signal for calculating the channel response has been described. However, the amplitude and phase are known and symbols that can be generated on the receiving side are described. If so, it can be used as a reference signal for calculating a channel response.

  As described above, when the channel response is obtained by referring to the SP signal, the channel responses in all symbols and subcarriers cannot be obtained directly. In order to obtain channel responses in all symbols and subcarriers, it is necessary to perform interpolation processing for the symbols and subcarrier directions.

線形補間法の場合

As the symbol direction interpolation method, for example, the following latest value holding method and linear interpolation method can be used. The interpolation unit 214 can perform an interpolation process according to the formula (3) or the formula (4).
In the case of the latest value retention method

For linear interpolation

Further, as an interpolation method in the subcarrier direction, for example, the following linear interpolation method can be used. The interpolation unit 214 can perform interpolation processing according to Expression (5).

ここで、ｘ_ｉ，ｋは、第２のＦＦＴ部１７の出力するキャリヤシンボル、ｙ_ｉ，ｋは、チャネル等化部２２の出力する、チャネル等化後のキャリヤシンボルを示す。尚、図２に示したＯＦＤＭ信号受信装置２のチャネル等化部２２においても、同じ式（６）によりチャネル等化を行う。 [Channel equalization section]
Next, the channel equalizer 22 will be described. The carrier symbol output by the second FFT unit 17 in the OFDM signal receiving apparatus 1 shown in FIG. 1 includes transmission path distortion and an error in processing in the OFDM signal receiving apparatus 1 on the demodulation side (reception side). Yes. For this reason, it is necessary to divide the carrier symbol by the first channel response obtained using the SP signal in the first channel estimation unit 21 before the determination and decoding processing. The channel equalization unit 22 performs channel equalization according to Equation (6).

Here, x _{i, k} represents a carrier symbol output from the second FFT unit 17, and y _{i, k} represents a carrier symbol after channel equalization output from the channel equalization unit 22. Note that the channel equalization unit 22 of the OFDM signal receiving apparatus 2 shown in FIG. 2 also performs channel equalization according to the same equation (6).

[Second channel estimation unit]
Next, the second channel estimation unit 24 will be described. The second channel estimation unit 24 estimates data symbols (hereinafter referred to as “transmission signals”) when signals are generated by the ISDB-T modulator, and directly obtains channel responses in all symbols and subcarriers. . The symbol reproduction unit 241 of the second channel estimation unit 24 reproduces the transmission symbol by demapping and remapping the received carrier symbol in the symbol i and the subcarrier number k.

Assuming that the reproduction symbol obtained by the threshold value determination process of Equation (7) is d _{i, k} (the estimated value of the transmission signal), the channel response is obtained by Equation (8).

[Third channel estimation unit]
Next, the third channel estimation unit 25 will be described. The third channel estimator 25 extracts the multipath component based on the second channel response estimated by the second channel estimator 24, and then detects the multipath D / U detector 23 as a detection result. Based on the path D / U, the amplitude of the multipath replica component generated in the replica generation unit 14 is adjusted. Furthermore, the third channel estimation unit 25 interpolates the channel response to L times the number of subcarriers of the OFDM signal and outputs the result.

ここで、Ｋは、ＯＦＤＭ信号の全サブキャリヤ数を示す。 First, the main wave detection unit 251 of the third channel estimation unit 25 detects the main wave z _i from the received signal according to Expression (9).

Here, K indicates the total number of subcarriers in the OFDM signal.

ここで、αは０≦α≦１を満たす適応係数である。また、新たなチャネル応答ｖ_ｉ，ｋは、Ｃ／Ｎの劣化したマルチパスレプリカを含まないようにするため、式（１０）で表される適応処理が加えられている。新たなチャネル応答ｖ_ｉ，ｋは、厳密にはチャネル応答ではないが、説明を簡単にするため、チャネル応答という。 Since the channel response is represented by the sum of the main wave component and the multipath component, the multipath component can be obtained by subtracting the main wave component from the channel response. By multiplying the obtained multipath component by an adaptive coefficient and adding the main wave component, a new channel response v _{i, k} is obtained.

Here, α is an adaptive coefficient that satisfies 0 ≦ α ≦ 1. In addition, in order to prevent the new channel response v _{i, k} from including a multipath replica with a deteriorated C / N, an adaptive process represented by Expression (10) is added. The new channel response v _{i, k} is not strictly a channel response, but is referred to as a channel response for the sake of simplicity.

ここで、［・］↑Ｌは、比Ｌのインタポレーションを示し、アップサンプルとイメージ成分の除去を含むものとする。また、ｌは、ＯＦＤＭ信号のサブキャリヤ周波数間隔に対し、Ｌ分の１の周波数間隔における周波数番号を示し、０≦ｌ＜ＬＫである。比Ｌを２のべき乗とすることにより、レプリカ生成のための時間−周波数領域変換に高速演算アルゴリズムであるＦＦＴ対を用いることができるため、好適である。 Next, the interpolator 255 of the third channel estimation unit 25 performs the interpolation of the ratio L with respect to the channel responses v _{i, k} and calculates the channel response within the subcarrier frequency band of the OFDM signal.

Here, [•] ↑ L indicates an interpolation of the ratio L, and includes up-sampling and removal of image components. Further, l indicates a frequency number in a frequency interval of 1 / L with respect to the subcarrier frequency interval of the OFDM signal, and 0 ≦ l <LK. Setting the ratio L to a power of 2 is preferable because an FFT pair that is a high-speed calculation algorithm can be used for time-frequency domain conversion for replica generation.

Since V _{i, l} is a channel response after the multipath is canceled, the channel response C _{i, l} for generating a multipath replica is calculated by updating according to the equation (12).

ここで、Ｘ_ｉ，ｌは、第１のＦＦＴ部１３の出力する周波数領域信号、Ｒ_ｉ，ｌは、マルチパスレプリカの周波数領域信号を示す。 [Replica generation unit]
Next, the replica generation unit 14 will be described. Based on the third channel response C _{i, l} output from the third channel estimation unit 25 of the channel estimation unit 18, the replica generation unit 14 calculates the multipath replica component included in the received signal by Expression (13). Generate.

Here, X _{i, l} represents a frequency domain signal output from the first FFT unit 13, and R _{i, l} represents a frequency domain signal of a multipath replica.

ここで、ｎは、遅延プロファイルの離散時間を示す。 [Multipath D / U detector]
Next, the multipath D / U detection unit 23 will be described. The IFFT unit 231 of the multipath D / U detection unit 23 obtains a delay profile by _performing IFFT on the first channel response u _{ip, kp} output from the first channel estimation unit 21.

Here, n indicates the discrete time of the delay profile.

ここで、ｎ_ｇは、ＧＩ長に相当するサンプル数を示す。 The main wave detection unit 232 detects the maximum value of the amplitude in the entire sample time of the delay profile, and outputs the main wave sample time n ₀ and its amplitude A ₀ . The detection range setting unit 233 sets a range in which a multipath having a delay time within the GI length exists as shown in Expression (15).

Here, _ng indicates the number of samples corresponding to the GI length.

ここで、式（１６）におけるＤＵＲは、遅延時間がＧＩ長以内であるマルチパス素波のＤ／Ｕのうちの最小値であり、マルチパスＤ／Ｕ検出部２３は、Ｄ／Ｕの最小値を求めているに過ぎない。 Maximum value detecting section 234, among the delay profile output from the IFFT unit 231, and outputs those having the maximum amplitude among the sample time n satisfying the equation (15) as _{A m.} The division unit 235 outputs the calculation result DUR of Expression (16) as a multipath D / U.

Here, the DUR in the equation (16) is the minimum value of the D / Us of multipath elementary waves whose delay time is within the GI length, and the multipath D / U detection unit 23 determines the minimum D / U. I'm just looking for a value.

[Adaptive coefficient setting section]
Next, the adaptive coefficient setting unit 258 in the third channel estimation unit 25 will be described. The adaptive coefficient setting unit 258 sets an adaptive coefficient α for determining the size of the multipath replica generated by the replica generation unit 14. If the multipath delay time is within the GI length, the replica generation unit 14 generates a replica, and the subtraction units 16 and 33 perform subtraction processing, so that the channel or the like can be obtained without canceling the multipath. The equalizing unit 22 can normally perform channel equalization. In this case, the adaptive coefficient α in the equation (10) is reduced or made zero, so that the C / N is not deteriorated by the subtraction of the multipath replicas in the subtraction units 16 and 33 and the channel equalization unit 22 is normal. And a correct received bit string can be obtained. On the other hand, by reducing α, the multipath equalization characteristic whose delay time exceeds the GI length is degraded. Therefore, the adaptive coefficient setting unit 258 may set a constant of 0 ≦ α ≦ 1 according to the magnitude of the multipath D / U that is the calculation result of Expression (16).

[Multipath replica subtraction]
Next, the subtracting units 16 and 33 that perform multipath replica subtraction will be described. The time domain signal of the multipath replica output from the IFFT unit 15 corresponds to the multipath component included in the equivalent baseband signal output from the orthogonal demodulation unit 12. Therefore, in the OFDM signal receiving apparatus 1 shown in FIG. 1, the subtraction unit 16 subtracts the multipath replica from the equivalent baseband signal output from the orthogonal demodulation unit 12, thereby canceling the multipath component.

  The subtracting unit 16 of the OFDM signal receiving apparatus 1 illustrated in FIG. 1 subtracts the multipath replica from the received signal in the time domain, whereas the subtracting unit 33 of the OFDM signal receiving apparatus 2 illustrated in FIG. Subtraction is performed in the frequency domain. Note that the DFT (Discrete Fourier Transform) pair or the FFT (Fast Fourier Transform) pair, which is a high-speed calculation algorithm thereof, satisfies linearity, and therefore the OFDM signal receiving apparatus 1 shown in FIG. It can be said that this is equivalent to the OFDM signal receiving apparatus 2 shown in FIG.

[Repeater]
Next, a relay apparatus using the OFDM signal receiving apparatus 1 of the first embodiment shown in FIG. 1 will be described. FIG. 7 is a block diagram showing the configuration of the relay apparatus. The relay device 3 includes a reception antenna 301, a feeder cable 302, a reception filter 303, an OFDM signal reception device 1, a remapping unit 304, a switch 305, an IFFT unit 306, a GI addition unit 307, an orthogonal modulation unit 308, and a D / A conversion. Unit 309, frequency converter 310, transmission filter 311, feeder cable 312, and transmission antenna 313.

  The desired wave (OFDM wave) transmitted from the upper station is received by the receiving antenna 301 in the broadcast wave relay station including the relay device 3. The reception filter 303 inputs the reception signal output from the reception antenna 301 through the feeder cable 302, and removes unnecessary signal components outside the frequency band of the desired wave. The output signal of the reception filter 303 is input to a reception unit (not shown), AGC (Automatic Gain Control) amplification is performed so that the output level becomes constant, frequency conversion is performed, and the signal is input to the OFDM signal reception apparatus 1.

  The processing in the OFDM signal receiving apparatus 1 is as described above. The parallel data output from the demapping unit 19 in the OFDM signal receiving apparatus 1 is input to the remapping unit 304. The carrier symbol after channel equalization output from the channel equalization unit 22 in the OFDM signal receiving apparatus 1 is input to the switch 305. The remapping unit 304 receives the parallel data from the demapping unit 19, reproduces the symbol, and outputs the reproduced symbol to the switch 305.

  The switch 305 inputs the carrier symbol after channel equalization from the channel equalization unit 22, and also receives the reproduction symbol from the remapping unit 304, and selects one of the carrier symbol after channel equalization and the reproduction symbol. The selected symbol is output to IFFT section 306 as a transmission symbol. IFFT section 306 receives a transmission symbol from switch 305, performs an IFFT process on the carrier symbol, converts it to a time domain signal, and outputs it to GI adding section 307.

  GI adding section 307 receives the time domain signal from IFFT section 306, adds a GI to the beginning of the OFDM symbol, and outputs an equivalent baseband signal to quadrature modulating section 308. The quadrature modulation unit 308 receives the equivalent baseband signal from the GI addition unit 307, performs orthogonal modulation processing on the equivalent baseband signal, converts it to a digital IF signal, and outputs the digital IF signal to the D / A conversion unit 309. The D / A converter 309 receives the digital IF signal from the quadrature modulator 308, performs D / A conversion on the digital IF signal, and outputs the IF signal to the frequency converter 310. The frequency conversion unit 310 receives the IF signal from the D / A conversion unit 309, frequency-converts the IF signal to the RF band, amplifies the RF signal to a constant level, and outputs the amplified signal to the transmission filter 311. The transmission filter 311 receives the RF signal from the frequency conversion unit 310 and removes unnecessary radiation components outside the band. The transmission signal from which unnecessary components outside the band are removed by the transmission filter 311 is supplied to the transmission antenna 313 through the feeder cable 312 and radiated as radio waves.

  The relay apparatus 3 shown in FIG. 7 includes the OFDM signal receiving apparatus 1 of the first embodiment shown in FIG. 1, but instead, the OFDM signal receiving apparatus 2 of the second embodiment shown in FIG. You may make it provide.

  The relay device 3 illustrated in FIG. 7 includes the demapping unit 19 and the remapping unit 304 of the OFDM signal receiving device 1, but is not necessarily required. The threshold value determination process by the demapping unit 19 and the remapping unit 304 is a process of replacing with a known transmission symbol closest to the input carrier symbol. This process has the advantage of removing equalization errors and white noise, but is not always necessary.

〔Experimental result〕
FIG. 10 is a diagram for comparing the required D / U by the conventional OFDM signal receiving apparatus and the required D / U by the OFDM signal receiving apparatus according to the embodiment of the present invention, with respect to the multipath delay time in a one-wave multipath environment. The required D / U is shown. 10A shows the required D / U in the normal OFDM signal receiving apparatus 100 shown in FIG. 8, and FIG. 10B shows the required D in the conventional OFDM signal receiving apparatus shown in Patent Document 1. FIG. 10C shows the required D / U in the OFDM signal receiving apparatus 1 of the first embodiment shown in FIG.

  Referring to FIG. 10A, in the normal OFDM signal receiving apparatus 100, when the multipath delay time is within the GI length, the required D / U is 0 dB, but when the delay time exceeds the GI length. The required D / U is 20 dB or more. Referring to FIG. 10B, in the conventional OFDM signal receiving apparatus, the required D / U is compared with that in the normal OFDM signal receiving apparatus 100 in the range where the multipath delay time exceeds the GI length. However, when the delay time is within the GI length, the required D / U increases as the delay time increases, and the required D / U becomes larger than that of the normal OFDM signal receiving apparatus 100. ing.

  On the other hand, referring to FIG. 10C, in the OFDM signal receiving apparatus 1 according to the first embodiment, when the multipath delay time is within the GI length, the required D / U as in the OFDM signal receiving apparatus 100 is obtained. Is 0 dB, and in the range where the delay time exceeds the GI length, the required D / U is smaller than that of the normal OFDM signal receiving apparatus 100 as in the conventional OFDM signal receiving apparatus. The required D / U in the OFDM signal receiving apparatus 2 according to the second embodiment shown in FIG. 2 is the same as that shown in FIG. 10C showing the required D / U in the OFDM signal receiving apparatus 1 according to the first embodiment. I was able to get it.

  As described above, as shown in the experimental results of FIG. 10, according to the OFDM signal receiving apparatus 1 of the first embodiment and the OFDM signal receiving apparatus 2 of the second embodiment, when the delay time is within the GI length, The reception characteristic can be the same as that of the normal OFDM signal receiving apparatus 100. Further, in the normal OFDM signal receiving apparatus 100, reception becomes impossible when the delay time exceeds the GI length. However, according to the OFDM signal receiving apparatus 1 of the first embodiment and the OFDM signal receiving apparatus 2 of the second embodiment, the delay is delayed. Even if the time exceeds the GI length, such multipath can be equalized. Furthermore, by using the OFDM signal receiving apparatus 1 according to the first embodiment or the OFDM signal receiving apparatus 2 according to the second embodiment, a relay apparatus that relays the upper station wave satisfactorily and stably can be realized.

It is a block diagram which shows the 1st structure of the OFDM signal receiver by embodiment of this invention. It is a block diagram which shows the 2nd structure of the OFDM signal receiver by embodiment of this invention. It is a block diagram which shows the structure of a 1st channel estimation part. It is a block diagram which shows the structure of a 2nd channel estimation part. It is a block diagram which shows the structure of a multipath D / U detection part. It is a block diagram which shows the structure of a 3rd channel estimation part. It is a block diagram which shows the structure of the relay apparatus using the OFDM signal receiver by embodiment of this invention. It is a block diagram which shows the structure of the conventional OFDM signal receiver. It is a block diagram which shows the other structure in the conventional OFDM signal receiver. It is a figure which compares the required D / U with respect to the delay time of a multipath between the conventional OFDM signal receiving apparatus and the OFDM signal receiving apparatus by embodiment of this invention.

Explanation of symbols

1, 2, 100, 101 OFDM signal receiving device 3 Relay device 10 Frequency converting unit 11 A / D converting unit 12 Orthogonal demodulating unit 13, 17, 30, 32, 44 FFT unit 14 Replica generating unit 15 IFFT unit 16, 33, 42 subtraction unit 18, 40 channel estimation unit 19 demapping unit 20 P / S conversion unit 21, 24, 25 channel estimation unit 22, 41 channel equalization unit 23 multipath D / U detection unit 43 adaptive filter unit 45 remapping unit 46 division unit 47 filter coefficient control unit 211 pilot extraction unit 212 pilot generation unit 213 division unit 214 interpolation unit 231 IFFT unit 232 main wave detection unit 233 detection range setting unit 234 maximum value detection unit 235 division unit 241 symbol reproduction unit 242 division unit 251 Main wave detection unit 252 Subtraction unit 253, 256 Multiplication unit 254 Addition unit 255 Interpolator 257 Delay unit 258 Adaptive coefficient setting unit 301 Reception antenna 302 Feeder cable 303 Reception filter 304 Remapping unit 305 Switch 306 IFFT unit 307 GI addition unit 308 Orthogonal modulation unit 309 D / A conversion unit 310 Frequency conversion unit 311 Transmission filter 312 Feeder Cable 313 Transmitting antenna

Claims (6)

An OFDM signal receiving apparatus that receives and demodulates an OFDM signal and outputs a bit string signal,
A channel estimator that calculates a channel response at a frequency interval that is a power of 2 with respect to a carrier interval of the OFDM signal from a transmission source to a reception point, and outputs the channel response;
An FFT unit that performs an FFT on the equivalent baseband signal after quadrature demodulation with the number of samples that is a power of 2 with respect to the effective symbol length of the OFDM signal, and outputs a frequency domain signal;
A replica generation unit that generates a multipath replica included in the OFDM signal based on a frequency domain signal output from the FFT unit and a channel response output from the channel estimation unit, and outputs a multipath replica;
An IFFT unit that outputs the multipath replica output from the replica generation unit with a number of samples that is a power of 2 times the effective symbol length of the OFDM signal, and outputs a time domain signal of the multipath replica;
A subtractor that subtracts the time domain signal of the multipath replica output from the IFFT unit from the equivalent baseband signal after quadrature demodulation and outputs the equivalent baseband signal after multipath cancellation;
An OFDM signal receiving apparatus, wherein the equivalent baseband signal after multipath cancellation output from the subtractor is subjected to FFT to equalize the channel and output the bit string signal. An OFDM signal receiving apparatus that receives and demodulates an OFDM signal and outputs a bit string signal,
A channel estimator that calculates a channel response at a frequency interval that is a power of 2 with respect to a carrier interval of the OFDM signal from a transmission source to a reception point, and outputs the channel response;
A first FFT unit that performs an FFT on the equivalent baseband signal after orthogonal demodulation with a number of samples that is a power of 2 with respect to the effective symbol length of the OFDM signal, and outputs a frequency domain signal;
A replica generation unit that generates a multipath replica included in the OFDM signal based on a frequency domain signal output from the first FFT unit and a channel response output from the channel estimation unit, and outputs a multipath replica; ,
An IFFT unit that outputs the multipath replica output from the replica generation unit with a number of samples that is a power of 2 times the effective symbol length of the OFDM signal, and outputs a time domain signal of the multipath replica;
A second FFT unit that performs FFT on the equivalent baseband signal after quadrature demodulation and outputs a carrier symbol;
FFT of the time domain signal of the multipath replica output from the IFFT section, and a third FFT section for outputting a carrier symbol of the multipath replica;
A subtractor for subtracting the carrier symbol of the multipath replica output by the third FFT unit from the carrier symbol output by the second FFT unit and outputting the carrier symbol after multipath cancellation,
An OFDM signal receiving apparatus characterized by channel equalizing a carrier symbol after multipath cancellation output from the subtracting section and outputting the bit string signal. The channel estimator is
A first channel estimation unit that performs channel estimation based on the pilot signal and outputs a channel response;
The carrier symbol obtained by performing FFT on the equivalent baseband signal after multipath cancellation in claim 1, or the carrier symbol after multipath cancellation output from the subtraction unit in claim 2 as the first channel estimation section. A channel equalization unit for performing the channel equalization by dividing by the channel response output by and outputting the carrier symbol after channel equalization;
The carrier symbol obtained by performing FFT on the equivalent baseband signal after multipath cancellation in claim 1, or the carrier symbol after multipath cancellation output from the subtraction unit in claim 2, and the output from the channel equalization unit A second channel estimator that performs channel estimation and outputs a channel response based on the channel-equalized carrier symbols,
Multipath D / U detection for detecting the minimum multipath D / U value with a delay time within GI length from the channel response output by the first channel estimation unit and outputting the multipath D / U minimum value And
Based on the channel response output by the second channel estimation unit and the multipath D / U minimum value output by the multipath D / U detection unit, a power of 2 with respect to the carrier interval of the OFDM signal Calculating a channel response at a frequency interval of 1 and outputting the channel response;
The OFDM signal receiving apparatus according to claim 1, wherein: The third channel estimator is
A main wave detection unit that detects a main wave component from the channel response output by the second channel estimation unit and outputs the main wave component;
A subtraction unit that subtracts the main wave component output from the main wave detection unit from the channel response output from the second channel estimation unit, extracts a multipath component, and outputs the multipath component;
An adaptive coefficient setting unit that sets an adaptive coefficient from the multipath D / U minimum value output by the multipath D / U detection unit, and outputs the adaptive coefficient;
Multiplying the multipath component output from the subtractor by the adaptive coefficient output from the adaptive coefficient setting unit, and a multiplier for outputting the multipath component after the adaptive coefficient multiplication,
An addition unit that adds the main wave component output from the main wave detection unit to the multipath component after multiplication of the adaptive coefficient output from the multiplication unit, and outputs a channel response after the addition;
An interpolator that interpolates the channel response after addition output from the adder to a power of 2 and outputs the channel response after interpolation;
A multiplier that multiplies the channel response after the interpolation output by the interpolator by a channel response before a predetermined unit update time, and outputs the channel response;
4. The OFDM signal receiving apparatus according to claim 3, further comprising: a delay unit that holds a channel response output from the multiplication unit for the unit update time and outputs a channel response before the unit update time. The first channel estimation unit includes:
A pilot symbol is extracted from the carrier symbol obtained by performing FFT on the equivalent baseband signal after multipath cancellation in claim 1, or from the carrier symbol after multipath cancellation output from the subtraction unit in claim 2, and the pilot A pilot extractor for outputting symbols;
A pilot generator that generates and outputs a pilot signal;
A pilot symbol output from the pilot extraction unit is divided by a pilot signal output from the pilot generation unit to obtain a channel response, and a division unit that outputs the channel response;
An interpolation unit that interpolates the channel response output by the division unit in the symbol direction and the subcarrier direction, and calculates channel responses in all subcarriers, and
The second channel estimation unit is
A symbol reproducing unit that reproduces a symbol by demapping and remapping the carrier symbol after channel equalization output by the channel equalizing unit, and outputs a reproduced symbol;
The symbol recovery unit outputs the carrier symbol obtained by performing FFT on the equivalent baseband signal after multipath cancellation in claim 1, or the carrier symbol after multipath cancellation output by the subtraction unit in claim 2. A division unit that divides by a reproduction symbol and outputs a channel response;
The multipath D / U detector is
IFFT unit that outputs a channel response output from the first channel estimation unit to a delay profile of a time domain signal and outputs the delay profile;
A main wave detection unit that detects a sample having the maximum amplitude among all samples of the delay profile output from the IFFT unit, and outputs the sample time and amplitude of the main wave component using the sample as a main wave component;
Using the sample time of the main wave component output from the main wave detector as a reference time, a sample time range in which the absolute value of the time difference from the reference time is within the GI length is set, and the sample time range is A detection range setting unit for outputting as a detection range;
In the delay profile output from the IFFT unit, the sample having the maximum amplitude is detected from the samples in the detection range output from the detection range setting unit, except for the sample of the main wave component. A maximum value detector that outputs the amplitude of a multipath component as a component;
A division unit that divides the amplitude of the main wave component output from the main wave detection unit by the amplitude of the multi-path component output from the maximum value detection unit, and outputs a multi-path D / U minimum value. The OFDM signal receiving apparatus according to claim 3 or 4, characterized in that:   The relay apparatus using the OFDM signal receiver as described in any one of Claim 1-5.

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