DE112014006182T5 - Receiving device and receiving method - Google Patents

Abstract

A receiving device generates reliability information that increases or decreases with the reliability of a demodulation signal in accordance with the information with the presence or absence of a narrow band noise component and its magnitude, and performs Viterbi decoding of the demodulation signal using the reliability information.

Description

TECHNICAL AREA

The present invention relates to a receiving apparatus and a receiving method of an OFDM (henceforth used as an abbreviation of Orthogonal Frequency Division Multiplex) signal.

BACKGROUND ART

In general, when data passing through convolutional coding is transmitted by OFDM, a receiving device performs Viterbi decoding of a demodulation signal of each individual subcarrier obtained from the received signal.

Here, the term "Viterbi decoding" refers to a decoding method that efficiently performs maximum likelihood decoding using a convolutional code repetitive structure.

For example, regarding an OFDM signal using Quadrature Phase Shift Keying (QPSK) or Quadrature Amplitude Modulation (QAM) as its primary modulation scheme, a Viterbi decoder first obtains branch metrics that estimate the likelihood between a received-point configuration of sub-carrier components passing through a phase and amplitude correction and a signal point configuration uniquely determined according to the modulation scheme. Then it gets all the surviving paths of a possible trellis, takes a cumulative sum of the branch metrics of the individual paths, and selects the path with the minimum cumulative sum. The Viterbi decoder outputs the state of the selected path as a decoding result and retrieves the transmission data.

It is known that the error correcting capability of the Viterbi decoder is improved by taking into account the reliability, i. the probability of the demodulation signal for each individual subcarrier is improved in calculating the branch metrics.

As to a reception apparatus of an OFDM signal using a subcarrier modulation scheme such as QPSK or QAM, concrete methods have already been proposed which use the reliability information for each individual subcarrier for the branch metric calculation.

However, the previous reliability information is calculated from the power information for each individual subcarrier, which has been obtained from an estimation result of the transmission line characteristics. Accordingly, the reliability information can not be applied to a signal such as a signal (hereinafter referred to as "DQPSK-OFDM signal") that undergoes primary modulation of convolutional coded data by DQPSK (Differential Quadrature Phase Shift Keying) and transmitted by OFDM. in this signal, the transmission line characteristics are not estimated in the demodulation.

In addition, during the differential demodulation of DQPSK, there are some cases where a constellation of the demodulation signal points with respect to the line Q = I or Q = -I (line at a 45 degree angle with the I and Q axes) on an IQ Level skew, depending on such factors as a sudden time variation of transmission line characteristics, AFC (Automatic Frequency Control) errors and phase noise. Thus, the reliability information can not be generated by using only the power information for each individual subcarrier.

For example, Patent Document 1 discloses a receiving technique for solving the foregoing problems. A receiving apparatus described in Patent Document 1, a receiving apparatus for receiving a DQPSK OFDM signal, for performing Viterbi decoding comprises a phase-shifter decision circuit for converting the fast discrete Fourier transform (FFT). Outputting a received signal into phase information, and calculating a soft decision value from the phase difference information between adjacent symbols; and a weighting coefficient generating circuit for calculating a weighting coefficient from the amplitude (or power, or a scalar value proportional thereto) of the FFT output of the two adjacent symbols.

When the output of the phase-shifter decision circuit is the demodulation signal of the DQPSK signal, the Viterbi decoding is performed by multiplying the output of the phase-shifter decision circuit by the weighting coefficient for each individual subcarrier, the weighting-coefficient generating circuit generated. At this time, the weighting coefficient represents the reliability of the demodulation signal, and with an increase in its value, the reliability is considered to be improved.

On a frequency selective fading transmission line, not only does a C / N (carrier power-to-noise ratio) vary for each individual subcarrier, but the quality of the demodulation signal degrades due to the time variation of the transmission line characteristics, the AFC error and the phase noise, as above described. Thus, using only the demodulation signal can not achieve sufficient Viterbi decoding performance.

In contrast, according to the technique of Patent Document 1, since it performs Viterbi decoding using phase rotation and amplitude information of the demodulation signal, it can improve the reception performance in comparison with the soft decision decoding using only the phase information.

DOCUMENT OF THE PRIOR ART

Patent Document

• Patent Document 1: Publication of Japanese Patent No. 11-196141 ,

DISCLOSURE OF THE INVENTION

PROBLEMS TO BE SOLVED BY THE INVENTION

On the other hand, in a real radio environment, there are some cases where the reception performance drops noticeably, not only because the previous demodulation signal deteriorates, but also because narrowband noise is superimposed on the signal band.

However, conventional techniques typified by Patent Document 1 consider that the reliability of the demodulation signal of the subcarriers increases with the amplitude (or the power or a scalar value proportional thereto) of the demodulation signal. Accordingly, they consider that the reliability of a demodulation signal of a sub-carrier is high, which increases its performance because the narrow-band noise is superimposed thereon, which offers a problem of reducing the error correction capability of the Viterbi decoding in contrast thereto.

The present invention is realized to solve the foregoing problems. Therefore, it is an object of the present invention to provide a receiving apparatus and a receiving method capable of increasing the error correcting capability of the Viterbi decoding and thus improving the receiving performance.

MEANS TO SOLVE THE PROBLEMS

A receiving apparatus in accordance with the present invention, which is a receiving apparatus for receiving an OFDM signal whose subcarriers are passed through a DQPSK modulation, comprises: a Fourier transform unit for performing a discrete Fourier transform of a received signal for each individual OFDM symbol and to output its result; a reference symbol extracting unit for extracting an output signal corresponding to a reference symbol from the output signal of the Fourier transform unit and outputting the extracted output signal; a narrow band noise detector for detecting a narrow band noise component included in the received signal in accordance with the output signal of the reference symbol extracting unit and outputting the presence or absence and the magnitude of the narrow band noise component for each individual subcarrier; a differential demodulator for performing a differential demodulation of the output signal of the Fourier transform unit and outputting a demodulation signal for each individual subcarrier; a reliability information generator for generating, in accordance with the output signals of the differential demodulator and the narrow band noise detector, reliability information that increases or decreases with the reliability of the demodulation signal, in response to the presence or absence information and the magnitude of the narrow band noise component; and a Viterbi decoder for performing Viterbi decoding of the demodulation signal using the reliability information.

ADVANTAGES OF THE INVENTION

According to the present invention, it offers an advantage of being capable of improving reception performance by increasing the error correction capability of Viterbi decoding.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 10 is a block diagram showing an embodiment of a receiving apparatus of an embodiment 1 in accordance with the present invention.

2 FIG. 10 is a block diagram showing an embodiment of a narrow-band noise detector of Embodiment 1. FIG.

3 FIG. 10 is a block diagram showing an embodiment of a reliability information generator of Embodiment 1. FIG.

4 FIG. 12 is a flowchart showing the operation of the receiving apparatus of Embodiment 1. FIG.

5 FIG. 12 is a diagram showing a CIR (Channel Impact Response) of a transmission line and frequency spectrums of OFDM transmitted and received signals when narrow band noise is present.

6 Fig. 10 is a block diagram showing an embodiment of a reliability information generator of an embodiment 2 in accordance with the present invention.

7 Fig. 10 is a block diagram showing an embodiment of a reliability information generator of an embodiment 3 in accordance with the present invention.

8th Fig. 10 is a block diagram showing another embodiment of the reliability information generator of the embodiment 3 in accordance with the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

The best mode for carrying out the invention will now be described in more detail with reference to the accompanying drawings for explaining the present invention.

EMBODIMENT 1

1 Fig. 10 is a block diagram showing an embodiment of a receiving apparatus of an embodiment 1 in accordance with the present invention. In the 1 The receiving apparatus shown is a receiving apparatus for receiving an OFDM signal resulting from performing a DQPSK modulation of subcarriers which are the individual carriers of an OFDM scheme. Incidentally, a transmission side uses a convolutional code as an error correction code of the transmission data and transmits it through an OFDM transmission scheme having a plurality of subcarriers using a differential modulation such as DQPSK or π / 4 shift DQPSK as the primary modulation.

A Fourier transform unit 1 performs, for each individual OFDM symbol, a Discrete Fourier Transform of the received signal S1 that has been converted to a baseband, and outputs its result. Incidentally, the individual subcarrier components transmitted by the OFDM scheme are obtained as a frequency domain signal received from the Fourier transform unit 1 has been issued.

A differential demodulator 2 performs a differential demodulation of the output signal of the Fourier transform unit 1 and outputs a demodulation signal for each individual subcarrier. The demodulation processing is performed by a complex multiplication of a complex conjugate signal of a subcarrier component of the previous OFDM symbol and a subcarrier component (complex signal) of the current OFDM symbol.

Incidentally, the output signal of the differential demodulator 2 a demodulation signal of the transmission signal transmitted through the individual subcarriers.

A reference symbol extracting unit 3 extracts a Fourier transform output signal corresponding to the reference symbol from the output signal of the Fourier transform unit 1 and spend it. Incidentally, the reference symbol, which is a known signal serving as a phase standard of the subcarriers, is inserted in the transmission signal at every fixed interval, for example, in the case of DAB (Digital Audio Broadcasting). A narrow band noise detector 4 detects the narrow band noise component included in the received signal from the output signal of the reference symbol extracting unit 3 , and outputs the magnitude of the narrow band noise component for each individual subcarrier.

In accordance with the information about the presence or absence of the narrow band noise component and its magnitude, generates a reliability information generator 5 the reliability information, which increases or decreases with the reliability of the demodulation signal, from the output signals of the differential demodulator 2 and the narrow band noise detector 4 and outputs the reliability information. For example, the reliability information generator uses 5 as the reliability information, a result of subtracting, the current power value of the demodulation signal, a predetermined constant multiple of the distance between the line Q = I or Q = -I on the IQ plane and a signal point of the demodulation signal, and a detection value of the narrow band noise component. In this case, the reliability of the demodulation signal is considered to increase with the value of the reliability information, and the reliability information is obtained by a Viterbi decoder 6 used to calculate the branch metric.

The Viterbi decoder 6 performs the Viterbi decoding of the demodulation signal by obtaining the branch metric indicative of the probability of the demodulation signal from the output signals of the differential demodulator 2 and the reliability information generator 5 , and outputs data S2 passing through the Viterbi decoding. For example, the Viterbi decoder receives 6 the branch metric indicating the probability of the demodulation signal from the demodulation signal (IQ signal) from the differential demodulator 2 and the reliability information supplied by the reliability information generator 5 has been fed. In addition, the Viterbi decoder receives 6 all the surviving paths of a possible trellis and retrieve the transmission data by selecting the paths that yield the minimum cumulative sum of the branch metrics of the paths.

What the Fourier transform unit 1 , the differential demodulator 2 , the reference symbol extracting unit 3 , the narrow band noise detector 4 , the reliability information generator 5 and the Viterbi decoder 6 Incidentally, they may be implemented as hardware circuits, by the way. Alternatively, the preceding components 1 - 6 for example, be realized as concrete means with hardware and software that cooperate with each other through a microcomputer that executes programs that describe the own processing of the present invention.

2 FIG. 10 is a block diagram showing an embodiment of the narrow-band noise detector in Embodiment 1. FIG. As in 2 shown includes the narrow band noise detector 4 a CIR detector 41 , an LPF unit 42 , a noise component extracting unit 43 , a decision threshold calculation unit 44 and a narrow band noise decision unit 45 ,

The CIR detector 41 detects a CIR (Channel Impulse Response) of each individual subcarrier by dividing the output signal of the reference symbol extracting unit 3 by the known reference symbol value corresponding to the output signal and outputs it.

The LPF unit 42 smoothes the output signal of the CIR detector 41 through a low pass filter and spend it. The pass band of the low-pass filter has a bandwidth required for passing a reflected wave component produced on the transmission line, that is, a bandwidth through which the reflected wave component appearing on the transmission line can pass. The use of such a passband makes it possible to smoothly smooth the CIR, thereby enabling appropriate detection of the narrow band noise component.

The noise component extracting unit 43 The noise component superimposed on the subcarrier extracts from the output signals of the CIR detector 41 and the LPF unit 42 and spend it. For example, it delays the individual subcarrier CIR signals from the CIR detector 41 have been output to determine the amount of signal delay to pass through the LPF unit 42 (for example, about 200 μs) and subtract that by the LPF unit 42 smoothed CIR signal from the delayed CIR signals. The subtraction result may be regarded as the noise components superimposed on the individual subcarriers, and calculating the instantaneous power of the subtraction result enables obtaining the noise power superimposed on the subcarriers.

The decision threshold calculation unit 44 receives the noise power for each individual sub-carrier detected by the noise component extractor 43 has been obtained, calculates its mean and calculates the decision threshold in accordance with the mean.

As the decision threshold, there is a value obtained by, for example, adding a predetermined value to the mean value or multiplying it by the mean value. Incidentally, on the transmission line without the narrow band noise, the noise component is mainly thermal noise, and its component is white noise, which is approximately uniformly distributed over the entire signal band. In this case, it is conceivable that the output signal of the noise component extracting unit 43 is approximately constant regardless of the subcarriers, and its value is approximately equal to the mean calculated as described above.

On the other hand, if the narrow-band noise is superimposed along with the thermal noise, the noise power of a subcarrier due to the narrow-band noise component increases. The use of the decision threshold calculated from the mean accordingly allows decision on the presence or absence of the narrowband noise.

The narrow band noise decision unit 45 The presence or absence of the narrow band noise for each individual subcarrier is determined from the result of comparing the output signal of the noise component extracting unit 43 with the decision threshold which complies with the decision threshold calculation unit 44 calculates, converts the presence or absence of the narrowband noise component and its size into binary or multi-level information and outputs the information.

As the binary information indicating the presence or absence and the size of the narrow band noise component, the narrow band noise decision unit outputs 45 a predetermined value if it decides that the narrow-band noise is present, but outputs 0 (zero) if it decides that the narrow-band noise is not present. For example, when outputting the presence or absence and the size as the multi-level information, the narrow-band noise decision unit issues 45 a value proportional to the power of the narrowband noise, if present, but outputs 0 (zero) if the narrowband noise is not present. In any case, there is a larger output value of the narrow band noise decision unit 45 a higher narrowband noise performance.

3 FIG. 10 is a block diagram showing an embodiment of the reliability information generator in Embodiment 1. FIG. As in 3 shown includes the reliability information generator 5 a subcarrier power detector 50 , a signal point quadrant converter 51 and a reliability information calculation unit 52 ,

The subcarrier power detector 50 generates a signal that is equal to or proportional to the power of the demodulation signal of each individual subcarrier, from the I signal, which is an inphase component, and the Q signal, which is the quadrature component of the demodulation signal (henceforth referred to as "IQ" Signal "), that is the differential demodulator 2 and outputs the signal that it generates.

The signal point quadrant converter 51 receives the IQ signal from the differential demodulator 2 , converts all of the quadrants in which the signal points are present on the IQ plane to the first quadrant, and outputs the result.

According to the output result of the sub-carrier power detector 50 , the output signal of the signal point quadrant converter 51 , the output signal of the narrow band noise detector 4 and a fixed coefficient k calculates the reliability information calculating unit 52 the reliability information with which the reliability of the demodulation signal increases or decreases in conformity with the power of the demodulation signal, the constellation of the demodulation signal and the magnitude of the narrow band noise component. Incidentally, the reliability information that is the reliability information calculation unit becomes 52 calculated by the post-stage Viterbi decoder 6 used to generate the branch metric.

Next, the operation will be described. 4 FIG. 12 is a flowchart showing the operation of the receiving apparatus of Embodiment 1. FIG. Incidentally, as far as the configuration of the receiving apparatus of Embodiment 1 is concerned, we shall become 1 to 3 refer.

First, the Fourier transform unit performs 1 the discrete Fourier transform of the received signal S1 for each individual OFDM symbol (step ST1). What the Fourier transform output signal corresponding to the reference symbol in the output signal of the Fourier transform unit 1 applies, extracted here, the reference symbol extracting unit 3 and deliver it to the narrowband noise detector 4 (YES at step ST2). On the other hand, the differential demodulator performs 2 the processing of the Fourier transform output signal corresponding to the signal other than the reference symbol in the output signal of the Fourier transform unit 1 off (NO at step ST2).

In the narrowband noise detector 4 detects the CIR detector 41 a CIR for each individual subcarrier by dividing the output signal of the reference symbol extracting unit 3 by the known reference symbol value corresponding to the output signal (step ST3). Here, C (n) denotes the CIR corresponding to the nth subcarrier in the OFDM symbols.

After that, the LPF unit performs 42 of the narrow band noise detector 4 the low pass filter (LPF) processing is performed on the C (n) by the CIR detector 41 has been detected to smooth it (step ST4). The CIR of the nth subcarrier passing through the smoothing is denoted L (n).

Next, the noise component extraction unit extracts 43 the narrow band noise component superimposed on the subcarrier from the output signals of the CIR detector 41 and the LPF unit 42 (Step ST5). For example, the noise component extracting unit delays 43 the CIR signal C (n) of the nth subcarrier output from the CIR detector 41 to the extent of the through the LPF unit 42 provided signal delay. Then it subtracts the CIR signal L (n) of the nth subcarrier, through the LPF unit 42 has been smoothed by the delayed CIR signal C (n), whereby the noise component Nz (n) (power value) superimposed on the n-th subcarrier is obtained. By the way, the extraction processing will be the noise component for all of the subcarriers.

Thereafter, the decision threshold calculation unit receives 44 successively the noise component Nz (n) for each individual sub-carrier detected by the noise component extracting unit 43 has been extracted, calculates the mean value thereof, and calculates the decision threshold T from the mean value (step ST6). Incidentally, the decision threshold T is a value obtained by adding a predetermined value to the average or obtained by multiplying them.

The narrow band noise decision unit 45 For example, the presence or absence of the narrowband noise for each individual subcarrier determines whether or not the noise component Nz (n) is greater than the decision threshold T (step ST7).

If the noise component Nz (n) is greater than the decision threshold T, that is, if the narrow-band noise component is detected (YES in step ST7), the narrow-band noise decision unit outputs 45 the binary information or multilevel information indicating the size of the narrow band noise component (step ST8).

In addition, when the noise component Nz (n) is not greater than the decision threshold T, that is, when the narrow-band noise component is not detected (NO at step ST7), the narrow-band noise decision unit also outputs 45 the binary information or multi-level information indicating that there is no narrow-band noise component is present (step ST9).

For example, the narrow band noise decision unit is 45 Z (n) indicating the size of the narrow band noise component superimposed on the nth subcarrier. If the narrow-band noise is detected, Z (n) assumes a value greater than 0 (zero), and unless the narrow-band noise is detected, Z (n) assumes a value of 0 (zero).

The differential demodulator 2 performs the differential demodulation of the Fourier transform output signal corresponding to the symbols other than the reference symbol in the output signal of the Fourier transform unit 1 and outputs the demodulation signal of each individual subcarrier (step ST10). The term "demodulation processing" refers to the processing which performs a complex multiplication of the complex conjugate signal of the subcarrier component of the previous OFDM symbol and the subcarrier component (complex signal) of the current OFDM symbol. Thus, the in-phase component I (n) and the quadrature component Q (n) of the demodulation signal of the n-th subcarrier are obtained.

Next, in the reliability information generator, it is detected 5 according to the in-phase component I (n) and the quadrature component Q (n) of the demodulation signal, which the differential demodulator 2 the subcarrier power detector 50 the power of the demodulation signal or P (n) proportional to the power for each individual subcarrier (step ST11).

For example, P (n) is a value resulting from adding the square of the in-phase component I (n) and the square of the quadrature component Q (n). Since the input signal to the subcarrier power detector 50 a result of the differential demodulation by the differential demodulator 2 Incidentally, P (n) does not accurately represent the power of the subcarrier demodulation signal. However, since the demodulation signal resulting from the differential demodulation is a signal obtained by the complex multiplication of the adjacent OFDM symbols, P (n) is a value proportional to the power of the demodulation signal of the subcarrier.

The signal point quadrant converter 51 receives the demodulation signal (IQ signal), which is the differential demodulator 2 and converts all the quadrants where a signal point is on an IQ plane to the first quadrant (step ST12).

For example, if the signal point of the demodulation signal of the nth subcarrier that has been received is present in the first quadrant on the IQ plane, the signal point quadrant converter outputs 51 the in-phase component I (n) and quadrature component Q (n) of the received demodulation signal as they are. Thus, the signal point (Id (n), Qd (n)) after the conversion is Id (n) = I (n), Qd (n) = Q (n).

In contrast, when the signal point of the demodulation signal is present in the second quadrant on the IQ plane, the signal point quadrant converter outputs 51 instead of the in-phase component I (n) and quadrature component Q (n) of the demodulation signal, the signal point (Id (n), Qd (n)) after conversion Id (n) = -I (n) and Qd (n) = Q (n).

In addition, when the signal point of the demodulation signal is present in the third quadrant on the IQ plane, the signal point quadrant converter outputs 51 instead of the in-phase component I (n) and quadrature component Q (n) of the demodulation signal, the signal point (Id (n), Qd (n)) after the conversion Id (n) = -I (n) and Qd (n) = -Q (n) off.

When the signal point of the demodulation signal is present in the fourth quadrant on the IQ plane, the signal point quadrant converter outputs 51 moreover, instead of the in-phase component I (n) and quadrature component Q (n) of the demodulation signal, the signal point (Id (n), Qd (n)) after the conversion Id (n) = I (n) and Qd (n ) = -Q (n).

According to the demodulation signal point (Id (n), Qd (n)) leading to the first quadrant by the signal point quadrant converter 51 and the output signal Z (n) of the narrow band noise detector 4 Next, calculate the reliability information calculation unit 52 the distance D (n) between the line Q = I on the IQ plane and the demodulation signal point of (step ST13). Incidentally, although the foregoing description is made as to the case of converting the signal point of the demodulation signal to the first quadrant, it is also possible to convert it to a signal point in the second quadrant or fourth quadrant, and the distance between the signal point and the line Q = Use -I as D (n).

Using the power information P (n) of the demodulation signal of the nth subcarrier, the distance D (n) between the line Q = I and the demodulation signal point of the nth subcarrier on the IQ plane, the detection value Z (n) of the narrow band noise that is superimposed on the nth sub-carrier and the positive fixed coefficient k next calculates the reliability information calculating unit 52 the reliability information R (n) of the demodulation signal of the nth subcarrier according to the following expression (1) (step ST14). Thus, the reliability information R (n) takes a value that increases or decreases in accordance with the presence or absence and the size of the narrow-band noise component superimposed on the subcarrier. R (n) = P (n) -k * D (n) -Z (n) (1)

Thereafter obtained according to the reliability information generator 5 received reliability information R (n), the Viterbi decoder 6 the branch metric indicating the probability of the demodulation signal (I (n), Q (n)) of the nth subcarrier, that of the differential demodulator 2 has been received, performs the Viterbi decoding of the demodulation signal, and outputs the Viterbi decoding-resultant data S2 (step ST15).

In performing error correction by the Viterbi decoding, the conventional receiving device performs the Viterbi decoding using the power value of the demodulation signal passing through the differential demodulation and / or the phase error information indicating the misalignment of the constellation of the demodulation signal on the IQ plane is.

In contrast, according to the present invention, it performs the Viterbi decoding in consideration of the presence or absence and the magnitude of the narrow band noise superimposed on the signal band, in addition to the power value of the demodulation signal and the skew of the constellation of the demodulation signal. Accordingly, it can increase the error correction capability for the DQPSK OFDM signal and improve the reception performance.

In the transmission based on the OFDM scheme, a transmission side allocates a plurality of subcarriers to the transmission data, as in FIG 5 (a) and performs digital modulation using DQPSK or the like in the individual subcarriers. In addition, the signal power of each individual subcarrier, affected by the multipath fading or the frequency selective fading by the transmission line, varies depending on the frequency of the subcarrier, as in FIG 5 (b) shown.

If the phase of the demodulation signal is not shifted from its original phase (π / 4, 3π / 4, -3π / 4, -π / 4), a subcarrier with high signal power is usually immune to thermal noise except for a particular radio environment, where the same channel interference occurs at a certain frequency, so that it can be safely said that the reliability of the demodulation signal is higher.

However, if the narrow band noise is superimposed on the signal band, since the power of the noise component is added to the signal power of the subcarrier, as in 5 (c) However, it is not always true that the performance value itself represents reliability.

Moreover, although an ideal signal point of the demodulation signal exists on the line Q = I or Q = -I on the IQ plane in DQPSK, since the information is superimposed not on the amplitude but on the phase, it can not do so at the four ideal signal points as determined by the QPSK.

Although it can be safely said in this case that the higher signal power of the subcarrier will provide a relatively better C / N, although the power is the same, the reliability of the demodulation signal is higher when / as the demodulation signal point is closer to the line Q = I or Q = -I.

Further, there are some cases where the constellation of the demodulation signal passing through the differential demodulation is skewed on an I / Q plane due to a time variation of the transmission line or a frequency error. In this case, it becomes more difficult to estimate the reliability according to only the power of the demodulation signal. Although the demodulation signal has the same power value, the reliability increases as / as the demodulation signal point approaches the line Q = I or Q = -I.

The foregoing expression (1) takes into account the foregoing characteristics in the OFDM signal whose subcarriers are subjected to the DQPSK modulation, and a larger calculation value of the foregoing expression (1) indicates higher reliability of the demodulation signal.

For example, a larger power information P (n) of the subcarrier gives a larger value R (n) and higher reliability. If the subcarrier demodulation signal exists on the line Q = I or Q = -I, which is an ideal signal point, the value D (n) = 0 and R (n) takes a higher value.

On the other hand, even if the constellation of the demodulation signal on the IQ plane is skewed, the closer the demodulation signal point to the line is Q = I or Q = -I, the smaller the value D (n) becomes, and R (n) takes one high value.

Since the detection value Z (n) of the narrow band noise component superimposed on the subcarrier takes a value corresponding to the presence or absence of the noise component and its magnitude, if the noise component does not occur and Z (n) is zero, further, R (n) a high value. Conversely, if the narrowband noise occurs and Z (n) increases, R (n) reduces in accordance with it.

As described above, according to the present embodiment 1, it comprises the Fourier transform unit 1 for performing a discrete Fourier transform of the received signal for each individual OFDM symbol and outputting its result; the reference symbol extracting unit 3 for extracting the output signal corresponding to a known reference symbol from the output signal of the Fourier transform unit 1 and outputting the output signal; the narrow band noise detector 4 for detecting a narrow band noise component included in the received signal from the output signal of the reference symbol extracting unit 3 and outputting the presence or absence and the magnitude of the narrow band noise component for each individual subcarrier; the differential demodulator 2 for performing a differential demodulation of the output signal of the Fourier transform unit 1 and outputting a demodulation signal for each individual subcarrier; the reliability information generator 5 for generating according to the output signals of the differential demodulator 2 and the narrow band noise detector 4 the reliability information that increases or decreases with the reliability of the demodulation signal in response to the information containing the presence or absence and the magnitude of the narrowband noise component; and the Viterbi decoder 6 for performing Viterbi decoding of the demodulation signal using the reliability information.

With such a configuration, it can generate the reliability information considering the presence or absence and the size of the narrow band noise component superimposed on the subcarriers. Thus, the Viterbi decoding using the reliability information can suppress the influence of the narrow-band noise on the demodulation signal. Accordingly, it can increase the error correction capability of the Viterbi decoding and improve the reception performance.

In addition, according to the present embodiment 1, the narrow band noise detector decides 4 in that the narrow band noise component is present in the frequency band in which the differential value between the CIR signal C (n) of the transmission line and the signal L (n) obtained by smoothing the CIR signal by the LPF is greater than is the predetermined decision threshold T, and the CIR signal C (n) is obtained by dividing the output signal corresponding to the reference symbol by the known value. Thus, it can suitably detect the narrow band noise superimposed on the subcarrier.

In addition, according to the present embodiment 1, since the low-pass filter has the pass band capable of passing the reflected wave component produced on the transmission line, it can properly smooth the CIR, thereby being capable of accurately detecting the narrow-band noise component.

Moreover, according to the present embodiment 1 of the Reliability information generator 5 the reliability information that increases or decreases with the reliability of the demodulation signal in accordance with the power information P (n) of the demodulation signal, the distance D (n) between the Q = I or Q = -I line on the IQ plane and the signal point of the demodulation signal, and the presence or absence and the magnitude Z (n) of the narrow band noise component. Thus, it enables Viterbi decoding using the reliability information corresponding to not only P (n) and D (n) but also Z (n). In addition, even if the constellation of the demodulation signal is skewed, it may suitably represent the reliability of the demodulation signal by D (n).

EMBODIMENT 2

6 Fig. 10 is a block diagram showing an embodiment of the reliability information generator of an embodiment 2 in accordance with the present invention. As in 6 shown includes the reliability information generator 5A an intra-symbol averaging unit 53 in addition to the configuration of the embodiment 1, and comprises instead of the reliability information calculation unit 52 a reliability information calculation unit 52A for calculating the reliability information using the information of the intra-symbol averaging unit 53 , By the way are in 6 the same components as these 3 are denoted by the same reference numerals, and their duplicate description will be omitted.

The intra-symbol averaging unit 53 , receiving the demodulation signal point (Id (n), Qd (n)) obtained by the conversion to the first quadrant by the signal point quadrant converter 51 the distance D (n) between the demodulation signal point and the line Q = I averages in the single OFDM symbol and outputs the average value D '(n).

Using the power information P (n) of the demodulation signal, the average value D '(n), the presence or absence, and the magnitude Z (n) of the narrow band noise component and the positive fixed coefficient k, the reliability information calculation unit calculates 52A the reliability information R (n), which increases or decreases with the reliability of the demodulation signal, according to the following expression (2). R (n) = P (n) -k * D '(n) -Z (n) (2)

Incidentally, although the foregoing description is made using an example that converts the signal point of the demodulation signal to the first quadrant, it is also possible to convert the signal point to the second or fourth quadrant to obtain the distance D (n) between the signal point and the second Line Q = -I and to use the mean of the values within the OFDM symbol.

As described above, according to the present embodiment 2, the reliability information generator is generated 5A the reliability information that increases or decreases with the reliability of the demodulation signal, in accordance with the power information P (n) of the demodulation signal, the average value D '(n) of the distance between the line Q = I or Q = -I on the IQ plane and the signal point of the demodulation signal for each individual OFDM symbol, and the presence or absence and the magnitude Z (n) of the narrowband noise component.

Thus, it can generate the reliability information in consideration of the phase rotation component common to all the subcarriers in the demodulation signal, thereby being capable of increasing the accuracy of the reliability information as compared with the foregoing embodiment 1.

EMBODIMENT 3

7 Fig. 10 is a block diagram showing an embodiment of the reliability information generator of an embodiment 3 in accordance with the present invention. As in 7 shown includes the reliability information generator 5B a phase error detector 54 and a modification coefficient converter 55 in addition to the embodiment of the embodiment 2, and comprises instead of the reliability information calculation unit 52A a reliability information calculation unit 52B for calculating the reliability information using the information from the modification coefficient converter 55 , By the way are in 7 the same components as these 3 and 6 are denoted by the same reference numerals, and their duplicate description will be omitted.

The phase error detector 54 , the signal point (I (n), Q (n)) of the demodulation signal from the differential demodulator 2 receiving, calculates a phase error θ (n) of the signal point on the IQ plane from the signal point and averages the phase error within the single OFDM symbol and outputs the mean value. Incidentally, as for θ (n), it may be calculated from an arctangent based on the signal point (I (n), Q (n)), and Q (n) / I (n) may be used as an approximate value.

In addition, the average of θ (n) within the single OFDM symbol assumes a value proportional to the average phase rotation amount in the differential demodulation signal of the OFDM symbol.

The modification coefficient converter 55 varies a positive modification coefficient m by which the distance D (n) between the line Q = I or Q = -I on the IQ plane and the signal point of the demodulation signal is multiplied, in such a manner that the positive modification coefficient m coincides with that Value increases in proportion to the average phase rotation amount in the demodulation signal.

Using the power information P (n) of the demodulation signal, the average value D '(n), the presence or absence, and the magnitude Z (n) of the narrow band noise component and the modification coefficient m, the reliability information calculation unit calculates 52B the reliability information R (n), which increases or decreases with the reliability of the demodulation signal, according to the following expression (3). R (n) = P (n) -m * D '(n) -Z (n) (3)

Incidentally, although the foregoing description is made using an example that converts the signal point of the demodulation signal to the first quadrant, it is also possible to convert the signal point to the second or fourth quadrant, the distance D (n) between the signal point and the Calculate line Q = -I and use the mean of the values within the OFDM symbol.

As in 8th In addition, a reliability information calculating unit may be shown 52C calculate the reliability information R (n) that increases or decreases with the reliability of the demodulation signal according to the following expression (4) using the power information P (n) of the demodulation signal, the distance D (n), the presence or absence, and the magnitude Z (n) of the narrow band noise component and the modification coefficient m. R (n) = P (n) - m · D (n) - Z (n) (4)

As described above, according to the present embodiment 3, the reliability information generator generates 5B the reliability information, which increases or decreases with the reliability of the demodulation signal, in accordance with the power information P (n) of the demodulation signal, the value m * D '(n), which is the mean of the distance between the line Q = I or Q = - I varies on the I-Q plane and the signal point of the demodulation signal for each individual OFDM symbol in accordance with the skew of the constellation of the demodulation signal, and the presence or absence and the magnitude Z (n) of the narrow band noise component. With such a configuration, it can obtain the reliability information which reflects the phase offset of the demodulation signal, ie, the skew of the constellation, more precisely than Embodiment 1 and Embodiment 2.

In addition, according to the present embodiment 3, the reliability information generator generates 5C the reliability information, which increases or decreases with the reliability of the demodulation signal, in accordance with the power information P (n) of the demodulation signal, the value m × D (n) representing the distance between the line Q = I or Q = -I on the IQ plane and the signal point of the demodulation signal varies in accordance with the inclination of the constellation of the demodulation signal, and the presence or absence and the size Z (n) of the narrow-band noise component. With such a configuration, it can realize a similar advantage as the previous advantage.

Incidentally, it should be understood that a free combination of the individual embodiments, variations of any components of the individual embodiments, or removal of any components of the individual embodiments are possible within the scope of the present invention.

INDUSTRIAL APPLICABILITY

A receiving apparatus in accordance with the present invention is capable of increasing error correction capability in Viterbi decoding and improving reception performance. Accordingly, it is suitable, for example, for a terrestrial digital broadcast receiver using an OFDM scheme.

DESCRIPTION OF THE REFERENCE SIGNS

• 1 Fourier transform unit; 2 differential demodulator; 3 Reference symbol extracting unit; 4 Narrow band noise detector; 5 . 5A . 5B . 5C Reliability information generator; 6 Viterbi decoder; 41 CIR-detector; 42 LPF unit; 43 Noise component extracting unit; 44 Decision threshold calculation unit; 45 Narrow band noise deciding unit; 50 Subcarrier power detector; 51 Signal point quadrant converter; 52 . 52A . 52B . 52C Reliability information calculation unit; 53 Intra-symbol averaging unit; 54 Phase error detector; 55 Modification coefficient converter

Claims (8)

A receiving device for receiving an OFDM signal whose subcarriers pass a DQPSK modulation, the receiving device comprising: a Fourier transform unit for performing a Discrete Fourier Transform of a received signal for each individual OFDM symbol and outputting its result; a reference symbol extracting unit for extracting an output signal corresponding to a reference symbol from the output signal of the Fourier transform unit and outputting the extracted output signal; a narrow band noise detector for detecting a narrow band noise component included in the received signal in accordance with the output signal of the reference symbol extracting unit and outputting the presence or absence and the magnitude of the narrow band noise component for each individual subcarrier; a differential demodulator for performing a differential demodulation of the output signal of the Fourier transform unit and outputting a demodulation signal for each individual subcarrier; a reliability information generator for generating, in accordance with the output signals of the differential demodulator and the narrow band noise detector, reliability information that increases or decreases with the reliability of the demodulation signal, in response to the presence or absence information and the magnitude of the narrow band noise component; and a Viterbi decoder for performing Viterbi decoding of the demodulation signal using the reliability information. The receiving apparatus according to claim 1, wherein the narrow-band noise detector decides that the narrow-band noise component is present in a frequency band in which a differential value between a channel impulse response signal of a transmission line and a signal obtained by flattening the channel impulse response signal by a low-pass filter is greater than a predetermined threshold , wherein the channel impulse response signal is obtained by dividing the output signal corresponding to the reference symbol by a known value. The receiving apparatus according to claim 2, wherein the low-pass filter has a pass band capable of passing a reflected wave component produced on the transmission line. The receiving apparatus according to claim 1, wherein the reliability information generator generates the reliability information that increases or decreases with the reliability of the demodulation signal in accordance with power information of the demodulation signal, a distance between a Q = I or Q = -I line on an IQ plane and a signal point of the demodulation signal, and the size of the narrow band noise component. The receiving apparatus according to claim 1, wherein the reliability information generator generates the reliability information that increases or decreases with the reliability of the demodulation signal in accordance with power information of the demodulation signal, an average of distances between a line Q = I or Q = -I on an IQ Level and signal points of the demodulation signal for the individual OFDM symbols, and the presence or absence and the size of the narrowband noise component. The receiving apparatus according to claim 1, wherein the reliability information generator generates the reliability information that increases or decreases with the reliability of the demodulation signal, in accordance with power information of the demodulation signal, a value that is a distance between a Q = I or Q = -I line an IQ plane and a signal point of the demodulation signal in accordance with a skew of a constellation of the demodulation signal modified, and the presence or absence and the size of the narrow-band noise component. The receiving apparatus according to claim 1, wherein the reliability information generator generates the reliability information that increases or decreases with the reliability of the demodulation signal, in accordance with power information of the demodulation signal, a value that is an average of a distance between a line Q = I or Q = - I varies on an IQ plane and a signal point of the demodulation signal for each individual OFDM symbol in accordance with a skew of a constellation of the demodulation signal, and the presence or absence and the magnitude of the narrow-band noise component. A receiving method for receiving an OFDM signal whose subcarriers pass a DQPSK modulation, the receiving method comprising the steps of: Performing, by a Fourier transform unit, a discrete Fourier transform of a received signal for each individual OFDM symbol and outputting its result; Extracting, by a reference symbol extracting unit, a Fourier transform output signal corresponding to a known reference symbol from the output signal of the Fourier transform unit and outputting the Fourier transform output signal; Detecting, by a narrow band noise detector, a narrow band noise component included in the received signal in accordance with the output signal of the reference symbol extracting unit and outputting the presence or absence and the magnitude of the narrow band noise component for each individual subcarrier; Performing, by a differential demodulator, a differential demodulation of the output signal of the Fourier transform unit and outputting a demodulation signal for each individual subcarrier; Generating, by a reliability information generator, in accordance with the output signals of the differential demodulator and the narrow band noise detector, reliability information that increases or decreases with the reliability of the demodulation signal in response to the presence or absence information and the magnitude of the narrow band noise component; and performing, by a Viterbi decoder, Viterbi decoding of the demodulation signal using the reliability information.

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