JP3845317B2 - Multipath interference canceling apparatus and method for FM receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a multipath interference canceling apparatus and method for an FM receiver that eliminates the effects of multipath interference occurring in the FM receiver.
[0002]
[Prior art]
In an FM receiver, a reflected wave generated by reflecting the direct wave on a building or the like interferes with an FM modulated wave (direct wave) transmitted from the transmitting antenna and directly input to the receiving antenna. As a result, a phenomenon called multipath interference in which a change in amplitude or phase occurs in the received signal and noise is generated in the output sound is known. For this reason, in a conventional FM receiver, when multipath interference is detected, the output sound is switched from stereo output to monaural output, or the high frequency component of the output sound is attenuated to give a noise feeling to the user. Is reduced.
[0003]
[Problems to be solved by the invention]
By the way, in the case of reducing the noise feeling due to multipath interference using the above-described conventional technology, the output sound is switched from stereo sound to monaural sound, so that the stereo feeling is lost or the high frequency component is attenuated. There has been a problem that the sound quality of the output sound is deteriorated, such as a feeling of being voluminous.
[0004]
The present invention was created in view of the above points, and an object of the present invention is to provide a multipath interference canceling apparatus for an FM receiver that can improve the sound quality of output speech by removing the influence of multipath interference. And to provide a method.
[0005]
[Means for Solving the Problems]
In order to solve the above-described problem, the multipath interference canceling apparatus for an FM receiver according to the present invention predicts a signal component caused by multipath interference by multipath prediction means, The signal component predicted by the path prediction unit is removed by the signal removal unit. By predicting the signal component generated by multipath interference and removing it from the intermediate frequency signal, it is possible to restore the intermediate frequency signal not subjected to multipath interference. Therefore, it is possible to improve the sound quality of the output sound without performing the process of switching the output sound from stereo sound to monaural sound or the process of attenuating the high frequency component of the output sound.
[0006]
The multipath prediction unit described above preferably includes a delay unit that delays the signal output from the signal removal unit for a predetermined time, and a level adjustment unit that adjusts the level of the signal delayed by the delay unit. By adjusting the signal level after delaying the signal output from the signal removing means for a predetermined time, the signal component generated by multipath interference, that is, the direct wave is reflected by the building etc. and delayed by a predetermined time. A signal generated by changing the signal level can be reproduced. Therefore, by removing the reproduced signal from the intermediate frequency signal, it is possible to restore the signal before receiving the multipath interference.
[0007]
The level adjusting means described above includes a level fluctuation detecting means for detecting a fluctuation in the signal level of the intermediate frequency signal, and a gain for performing the level adjustment according to the level fluctuation level detected by the level fluctuation detecting means. It is desirable to adjust the level of the signal after being delayed by the delay means with the gain set by the gain setting means. Since the signal level of the intermediate frequency signal fluctuates due to multipath interference, it is possible to accurately detect the presence or degree of multipath interference by detecting the fluctuation of the signal level of the intermediate frequency signal.
[0008]
The level fluctuation detecting means described above preferably detects the signal level based on the real part and the imaginary part of the intermediate frequency signal. In general, various signals can be represented by complex numbers, and the signal level can be accurately detected by extracting the real and imaginary parts of the complex numbers. Specifically, it is desirable that the level fluctuation detection means includes a Hilbert transform filter that separates the real part and the imaginary part, and an arithmetic means that obtains the square root after obtaining the square sum of the real part and the imaginary part. . The real part and the imaginary part of the input signal can be separated by the Hilbert transform filter, and the signal level (magnitude) of the input signal can be easily obtained by calculating the square root of these square sums.
[0009]
The level fluctuation detecting means described above includes a limiting means for setting a predetermined upper limit value and a lower limit value for the calculation result of the calculating means to limit the range of the output value, and a low frequency for the output value of the limiting means. It is desirable to further include low-pass means for passing only the components. As a result, it is possible to suppress an excessive reaction that occurs when the calculation result of the level fluctuation changes abruptly, and to stabilize the operation.
[0010]
It is desirable that the limiting means described above set the upper limit value and the lower limit value variably according to the average level of the intermediate frequency signal. As a result, it is possible to give an appropriate limit according to the average level of the intermediate frequency signal, and further to stabilize the operation. As the average level of the intermediate frequency signal used here, for example, the output value of an S meter that detects the effective value of the intermediate frequency signal may be used.
[0011]
Further, it is desirable that the above-described limiting means variably set the upper limit value and the lower limit value based on the signal output from the signal removal means. Alternatively, it is desirable that the limiting unit described above variably sets the upper limit value and the lower limit value based on the result of smoothing the absolute value of the signal output from the signal removal unit. The signal output from the signal removal means is a signal obtained by removing the multipath interference from the intermediate frequency signal input to the multipath interference cancellation apparatus of the present invention, and after such multipath interference is removed. By using the intermediate frequency signal, specifically, by using the result obtained by smoothing the absolute value of the intermediate frequency signal, it becomes possible to give an appropriate limit according to the average level of the intermediate frequency signal by the limiting means. Thus, the operation can be further stabilized. In addition, for example, unlike the case of obtaining the average level of the intermediate frequency signal based on the analog output signal of the S meter, the influence of the AC component included in the output of the S meter, the delay time when the analog output is digitized, etc. Since there is no need to consider this, the design of the multipath interference canceller and the entire FM receiver using the multipath interference canceller becomes easy.
[0012]
The gain setting means described above preferably selects one of a plurality of discrete gains prepared in advance within a range of 1 to 0 according to the level fluctuation of the intermediate frequency signal. This makes it possible to simplify the process for setting the gain.
[0013]
The multipath prediction means and the signal removal means are preferably realized by digital signal processing. By adopting digital signal processing, it is possible to simplify the configuration compared to the case of using analog circuits, etc., and there is almost no variation in characteristics or changes over time, making it easy to adjust operating conditions and change design. Become.
[0014]
The digital signal processing described above is preferably performed using a digital signal processing device. By using a digital signal processor (DSP), the processing speed can be increased and the configuration can be simplified. In particular, when another configuration of the FM receiver is performed by a digital signal processing device, the operation of the present invention can be performed using the digital signal processing device, and in this case, a special configuration needs to be added. Therefore, the device configuration of the entire FM receiver can be simplified.
[0015]
The FM receiver multipath interference canceling method according to the present invention includes a first step of predicting a signal component caused by multipath interference based on an input intermediate frequency signal, and the predicted signal component as multipath interference. A second step of removing the received intermediate frequency signal from the received intermediate frequency signal. Since the signal component generated by the multipath interference is predicted and the signal component is removed from the intermediate frequency signal, the intermediate frequency signal in a state where the multipath interference is not received can be restored. Therefore, it is possible to improve the sound quality of the output sound without performing the process of switching the output sound from stereo sound to monaural sound or the process of attenuating the high frequency component of the output sound.
[0016]
In the first step described above, it is desirable to predict a signal component caused by multipath interference by delaying the signal generated in the second step by the delay time of the received radio wave. By delaying the signal generated in the second step by a predetermined delay time, a signal component caused by multipath interference, that is, a reflection obtained by delaying the signal by a predetermined time by reflecting a direct wave on a building or the like. Waves can be reproduced. Therefore, by removing the reproduced signal from the intermediate frequency signal, it is possible to restore the signal before receiving the multipath interference.
[0017]
In the first step described above, it is desirable to determine the degree of multipath interference according to the magnitude of the change in the signal level of the intermediate frequency signal and adjust the level of the signal after being delayed by the delay time. . The signal level of the intermediate frequency signal is almost constant when it is not subjected to multipath interference, but when it is subjected to multipath interference, the amount of fluctuation varies depending on the degree. By adjusting the level of the delayed signal in accordance with the signal level fluctuation, the signal component caused by multipath interference can be accurately predicted.
[0018]
In the first step, the Hilbert transform is performed on the intermediate frequency signal to separate the real part and the imaginary part, and the degree of multipath interference is determined by obtaining the square root of the square sum of these. Is desirable. The real part and the imaginary part of the intermediate frequency signal can be separated by the Hilbert transform, and the signal level of the intermediate frequency signal can be easily obtained by calculating the square root of these square sums.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an FM receiver according to an embodiment to which the present invention is applied will be described with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of an FM receiver according to an embodiment. An FM receiver 100 shown in FIG. 1 includes an antenna 10, a front end unit (F / E) 12, a channel selection circuit 14, an intermediate frequency amplification circuit 18, a DSP (digital signal processing device) 20, a stereo demodulation circuit 26, and a control unit. 28 is comprised.
[0020]
The front end unit 12 includes an antenna tuning circuit, a harmonic amplification circuit, a local oscillation circuit, a mixing circuit, and the like, and a desired reception frequency (tuning frequency) from FM modulated waves (received radio waves) input from the antenna 10. ) The component is extracted, and a predetermined frequency conversion is performed on the extracted signal to output an intermediate frequency signal (IF signal).
[0021]
The channel selection circuit 14 is for setting the reception frequency, and constitutes a PLL (phase locked loop) together with the local oscillation circuit in the front end unit 12. For example, it has a frequency dividing circuit composed of a programmable counter, and by changing the frequency dividing ratio according to an instruction from the control unit 28, the oscillation frequency of the local oscillation circuit in the front end unit 12 is changed, and the reception frequency Switch.
[0022]
The intermediate frequency amplifier circuit 18 amplifies the intermediate frequency signal output from the front end unit 12 and performs a tuning operation, and outputs only a frequency component near 10.7 MHz. Further, the intermediate frequency amplification circuit 18 of the present embodiment incorporates an S meter that detects an effective value that is an average level of the intermediate frequency signal.
[0023]
The DSP 20 is a processor dedicated to digital signal processing, performs various processes based on an input intermediate frequency signal, and outputs a composite signal after FM detection. The DSP 20 includes a multipath scan cera (multipath interference canceller) 22 and an FM detection circuit 24.
[0024]
The multipath scan cella 22 performs processing for removing noise caused by multipath interference included in the intermediate frequency signal. The FM detection circuit 24 performs FM detection processing on the intermediate frequency signal output from the multipath scan celler 22 and outputs a composite signal.
[0025]
The stereo demodulation circuit 26 performs a stereo demodulation process for separating the composite signal output from the FM detection circuit 24 into an L signal and an R signal that constitute a stereo audio signal. The control unit 28 controls the overall operation of the FM receiver 100 such as setting the reception frequency.
[0026]
Next, a detailed configuration of the multipath scanceller 22 included in the DSP 20 will be described. FIG. 2 is a diagram showing a detailed configuration of the multipath scan 22. The multipath scanceller 22 includes analog-digital (A / D) conversion units 50 and 51, a level fluctuation detection unit 52, a coefficient setting unit 54, a multiplication unit 56, a subtraction unit 58, and a delay processing unit 60. .
[0027]
The analog-digital conversion unit 50 converts the analog intermediate frequency signal output from the intermediate frequency amplifier circuit 18 into digital data (intermediate frequency signal data). The analog-digital converter 51 converts the output signal of the S meter in the intermediate frequency amplifier circuit 18 into digital data (S meter output data).
[0028]
The level fluctuation detection unit 52 varies the signal level of the intermediate frequency signal based on the intermediate frequency signal data output from the analog-digital conversion unit 50 and the S meter output data output from the analog-digital conversion unit 51. Detect minute (level fluctuation).
[0029]
The coefficient setting unit 54 sets a predetermined coefficient according to the level fluctuation level detected by the level fluctuation detection unit 52, and outputs it to the multiplication unit 56. The coefficient set by the coefficient setting unit 54 becomes “gain” when adjusting the signal level of the signal output from the delay processing unit 60.
[0030]
FIG. 3 is a diagram illustrating a specific example of coefficients set by the coefficient setting unit 54. As shown in FIG. 3, the coefficient setting unit 54 of the present embodiment has 0, 0.2, 0.4, 0.6, 0 depending on the level fluctuation level detected by the level fluctuation detection unit 52. .8, Select one of the coefficients 1 and output. As described above, since the coefficient can be set by a simple process of selecting one of a plurality of discrete coefficients prepared in advance, the setting process can be simplified. In addition, the value of the coefficient shown here is an example, and is not limited to this.
[0031]
The multiplication unit 56 performs a calculation process of multiplying a predetermined coefficient output from the coefficient setting unit 54 by a signal (details will be described later) output from the delay processing unit 60. The signal output from the multiplier 56 corresponds to a signal in which a signal component generated by multipath interference is predicted. The subtracting unit 58 performs arithmetic processing for subtracting the prediction data of the signal component generated by multipath interference output from the multiplying unit 56 from the intermediate frequency signal data output from the analog-digital converting unit 50.
[0032]
The delay processing unit 60 performs a process of delaying the calculation result output from the subtraction unit 58 by a predetermined time. Specifically, the delay time in the delay processing unit 60 is the difference in arrival time between the direct wave input to the antenna 10 and the reflected wave input to the antenna 10 after the direct wave is reflected on a building or the like. The corresponding time is set.
[0033]
Next, a detailed configuration of the level fluctuation detection unit 52 will be described. FIG. 4 is a diagram illustrating a detailed configuration of the level fluctuation detection unit 52. 4 includes a Hilbert transform filter 70, two square calculation units 72 and 74, an addition unit 76, a square root calculation unit 78, a limiter 80, and a low-pass filter (LPF) 82. The level fluctuation detection unit 52 shown in FIG. .
[0034]
The Hilbert transform filter 70 performs Hilbert transform on the intermediate frequency signal data input from the analog-digital conversion unit 50, and separates the real part (I) and the imaginary part (Q) of the intermediate frequency signal expressed in a complex number. .
The square calculation unit 72 squares the real part of the intermediate frequency signal output from the Hilbert transform filter 70 (I ² ). The square calculation unit 74 squares the imaginary part of the intermediate frequency signal output from the Hilbert transform filter 70 (Q ² ). The adding unit 76 adds the calculation results of the square calculation units 72 and 74. The square root calculation unit 78 outputs signal level data of the intermediate frequency signal by performing calculation for obtaining the square root of the addition result obtained by the addition unit 76. Thus, the intermediate frequency signal is obtained by performing a mathematical process of separating the real part and the imaginary part of the intermediate frequency signal by performing the Hilbert transform and obtaining the square root of each square sum of the real part and the imaginary part. The signal level can be easily and reliably obtained.
[0035]
Based on the S meter output data (average level of the intermediate frequency signal) input from the analog-digital conversion unit 51, the limiter 80 is predetermined for the level fluctuation of the intermediate frequency signal output from the square root calculation unit 78. Set the upper and lower limit values to limit the output value range. Specifically, the limiter 80 sets an offset value corresponding to the effective value of the intermediate frequency signal based on the input S meter output data, and a predetermined range (for example, an offset value) with the offset value as a center value. The range of the output value is limited to be included in ± 0.05V). The low-pass filter 82 performs a filtering process of passing a low-frequency component below the carrier frequency of the intermediate frequency signal by removing the high-frequency component of the signal output from the limiter 80. In this way, by passing the calculation result output from the square root calculation unit 78 through the limiter 80 and the low-pass filter 82, it is possible to suppress an excessive reaction of the multipath scanceller 22 that occurs when the calculation result fluctuates rapidly. This makes it possible to stabilize the operation. In particular, by setting the upper limit value and lower limit value of the limit operation by the limiter 80 variably according to the average level of the intermediate frequency signal, it becomes possible to give an appropriate limit according to the effective value of the intermediate frequency signal, Furthermore, the operation can be stabilized.
[0036]
The level fluctuation detection unit 52, coefficient setting unit 54, multiplication unit 56, and delay processing unit 60 described above are a multipath prediction unit, a subtraction unit 58 is a signal removal unit, a delay processing unit 60 is a delay unit, and a level variation detection unit. 52, a coefficient setting unit 54, and a multiplication unit 56 respectively correspond to the level adjusting means. Further, the level fluctuation detection unit 52 is a level fluctuation detection unit, the coefficient setting unit 54 is a gain setting unit, the square calculation units 72 and 74, the addition unit 76, and the square root calculation unit 78 are calculation units, and the limiter 80 is a limiting unit. The low-pass filter 82 corresponds to the low-pass means.
[0037]
The FM receiver 100 of this embodiment has such a configuration, and the operation thereof will be described next.
First, the contents of the operation performed by the level fluctuation detection unit 52 will be described. FIG. 5 is a diagram illustrating an example of an intermediate frequency signal subjected to multipath interference, which is input to the level fluctuation detection unit 52. In FIG. 5, the horizontal axis corresponds to time, and the vertical axis corresponds to the signal level of the intermediate frequency signal. The signal level (carrier signal envelope) of the intermediate frequency signal when it is not subject to multipath interference is almost constant, but when it is subject to multipath interference, the intermediate frequency signal corresponding to the direct wave and the building As shown in FIG. 5, the signal level of the actual intermediate frequency signal output from the intermediate frequency amplifier circuit 18 varies greatly.
[0038]
FIG. 6 is a diagram showing an output value of the limiter 80 when the intermediate frequency signal shown in FIG. 5 is input. In FIG. 6, the horizontal axis corresponds to time, and the vertical axis corresponds to the output value (limiter output) of the limiter 80. By performing arithmetic processing using the Hilbert transform filter 70, the square calculation units 72 and 74, the addition unit 76, and the square root calculation unit 78 on the intermediate frequency signal data having the signal level fluctuation shown in FIG. An output value in which the level fluctuation is superimposed on the average level (effective value) of the intermediate frequency signal is obtained, but this output value is difficult to handle as it is because of the large level fluctuation. Therefore, the limiter output shown in FIG. 6 is obtained by using the limiter 80 to limit the output value range by setting the upper limit value and the lower limit value based on the average level of the intermediate frequency signal.
[0039]
FIG. 7 is a diagram showing a result of passing the limiter output shown in FIG. In FIG. 7, the horizontal axis corresponds to time, and the vertical axis corresponds to the output value (LPF output) of the low-pass filter 82. By passing the output value of the limiter 80 shown in FIG. 6 through the low-pass filter 82, frequency components higher than the carrier frequency are removed, and an output signal representing the degree of multipath interference is obtained as shown in FIG. That is, as can be seen from FIG. 7 with reference to FIG. 5, when receiving multipath interference, the signal level of the intermediate frequency signal greatly fluctuates, and the low-pass filter 82 corresponds to this large fluctuation. The output value of also changes greatly. On the other hand, when the multipath interference is not received, the signal level of the intermediate frequency signal does not fluctuate so much and the output value of the low-pass filter 82 is a value near zero. The output value of the low-pass filter 82 is input to the coefficient setting unit 54 as a detection result by the level fluctuation detection unit 52.
[0040]
Next, the overall operation of the multipath scan 22 will be described. The operation of the multipath scan 22 includes (1) a first step of predicting a signal component caused by multipath interference based on input intermediate frequency signal data, and (2) multipath interference of the predicted signal component. A second step of removing from the received intermediate frequency signal data.
[0041]
In the first step, first, the level fluctuation of the intermediate frequency signal due to the multipath interference is detected by the level fluctuation detecting unit 52, and the coefficient setting unit 54 determines the multipath interference level based on the detected level fluctuation magnitude. The degree is determined and a predetermined coefficient (see FIG. 3) is set. Then, the coefficient set by the coefficient setting unit 54 is multiplied by the intermediate frequency signal output from the delay processing unit 60 by the multiplication unit 56, thereby adjusting the level of the intermediate frequency signal. That is, the level adjustment of the intermediate frequency signal delayed by a predetermined delay time is performed, and a signal component caused by multipath interference is predicted by this processing.
[0042]
In the second step, the signal component output from the multiplier 56 in the first step, that is, the signal component caused by multipath interference is predicted from the current intermediate frequency signal data output from the analog-digital conversion unit 50. A subtraction process for removing the result is performed by the subtraction unit 58.
[0043]
By performing the processing described in the first and second steps described above, the signal component generated by multipath interference, that is, reflected by a building or the like is delayed by a predetermined time, and the signal level is changed and input to the antenna 10. The reflected wave can be restored. Therefore, by removing the restored signal component from the intermediate frequency signal, it is possible to restore the intermediate frequency signal before being subjected to multipath interference.
[0044]
FIG. 8 is a diagram illustrating a simulation result in which the operation of the multipath scan cella 22 is verified. In FIG. 8, the horizontal axis corresponds to time, and the vertical axis corresponds to the signal level of the modulated wave signal. A characteristic line to which a symbol A (a chain line) is attached indicates a signal obtained by synthesizing a sine wave of 10 kHz and 56 kHz set as a modulated wave and before FM modulation. A characteristic line to which a reference symbol B (solid line) is attached is a signal after the influence of multipath interference is removed using the multipath scanceller 22 of the present embodiment, and the signal after FM detection or stereo demodulation is performed. Show. A characteristic line to which a code C (dotted line) is attached indicates a signal from which the influence of multipath interference has not been removed, and has undergone FM detection and stereo demodulation.
[0045]
As can be seen by comparing the characteristic lines of code A and code C shown in FIG. 8, when the multipath interference is received, the original signal waveform changes to a signal that is not much in phase, and the signal quality of the received signal is reduced. It turns out that it falls. On the other hand, as apparent from the comparison of the characteristic lines of the code A and the code B, the waveform of the modulated wave signal can be reproduced almost accurately by using the multipath scanrer 22 of the present embodiment.
[0046]
As described above, the FM receiver 100 according to the present embodiment predicts a signal component caused by multipath interference and removes the signal component from the intermediate frequency signal. Therefore, the intermediate frequency in a state where the multipath interference is not received. The signal can be restored. Therefore, by removing the influence of multipath interference, it is possible to improve the sound quality of the output sound without performing the process of switching the output sound from stereo sound to monaural sound or the process of attenuating the high frequency components of the output sound. become. In addition, since the processing in the multipath scan cella 22 is realized by digital signal processing, the configuration can be simplified and the variation in characteristics and change with time can be reduced as compared with the case where an analog circuit or the like is used. There is an advantage that fine adjustment and design change can be facilitated. In particular, since a DSP, which is a processor dedicated to digital signal processing, is used, the processing speed can be increased and the configuration can be further simplified. In addition, if a configuration other than the multipath scan 22 has already been realized by the DSP, it is only necessary to incorporate the function of the multipath scan 22 in this DSP. The apparatus configuration of the entire 100 can be simplified.
[0047]
By the way, in the multipath scancella 22 described above, the limiter 80 in the level fluctuation detection unit 52 is operated based on the output signal of the S meter in the intermediate frequency amplifier circuit 18. Considering the influence of the components, the delay time due to digitization, and the like, it is desirable to generate an equivalent signal in the multipath scan 22.
[0048]
FIG. 9 is a diagram showing a detailed configuration of a modified example of the multipath scancera. The multipass scan cell 22A shown in FIG. 9 omits the A / D conversion unit 51 and adds an absolute value processing unit 62 and a low pass filter (LPF) 64 to the multi pass scan cella 22 shown in FIG. Is different.
[0049]
The absolute value processing unit 62 calculates the absolute value of the digital intermediate frequency signal (IF signal) that is the output of the multipath scan 22A. The low pass filter 64 smoothes the output of the absolute value processing unit 62. The smoothed output of the low-pass filter 64 is input to the limiter 80 in the level fluctuation detection unit 52.
[0050]
In this way, by generating a signal for operating the limiter 80 in the level fluctuation detector 52 based on the output of the multipath scan 22A itself, a series of operations from detection of multipath interference to multipath cancellation can be performed. It can be completed in the passscancera 22A. This eliminates the need to consider the influence of the AC component of the S meter in the intermediate frequency amplifier circuit 18, the delay time when digitized, and the like, so that the multipath scan 22A and the entire FM receiver using the same can be designed. It becomes easy.
[0051]
In addition, this invention is not limited to the said embodiment, A various deformation | transformation implementation is possible within the range of the summary of this invention. For example, in the above-described embodiment, the multipath scan cera 22 is provided in the DSP 20 which is a digital signal processing dedicated device, and the processing is performed. The function may be realized. Further, the function of the multipath scan 22 may be realized by configuring an equivalent functional block using an analog circuit.
[0052]
In the above-described embodiment, the multipath scan cell 22 and the FM detection circuit 24 are included in the DSP 20, but the range of functional blocks included in the DSP 20 is not limited to this, and various modifications can be considered. For example, only the multipath scan 22 may be realized by a DSP, and the FM detection circuit and subsequent functional blocks may be realized by an analog circuit. In addition to the multipath scan 22 and the FM detection circuit 24, the stereo demodulation circuit 26 in the subsequent stage and other functional blocks (not shown) such as a functional block for adjusting the sound quality of the output sound are all realized by the DSP. May be.
[0053]
The present invention can be widely applied to all FM receivers that receive FM modulated waves in addition to FM receivers that receive FM broadcast radio waves.
[0054]
【The invention's effect】
As described above, according to the present invention, a signal component caused by multipath interference is predicted, and this signal component is removed from the intermediate frequency signal. Therefore, it is possible to restore the intermediate frequency signal that has not been subjected to multipath interference. it can. Therefore, it is possible to improve the sound quality of the output sound without performing the process of switching the output sound from stereo sound to monaural sound or the process of attenuating the high frequency component of the output sound.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a configuration of an FM receiver according to an embodiment.
FIG. 2 is a diagram showing a detailed configuration of a multipath scancella.
FIG. 3 is a diagram illustrating a specific example of coefficients set by a coefficient setting unit.
FIG. 4 is a diagram showing a detailed configuration of a level fluctuation detection unit.
FIG. 5 is a diagram illustrating an example of an intermediate frequency signal subjected to multipath interference.
FIG. 6 is a diagram illustrating an output value of a limiter.
FIG. 7 is a diagram illustrating a result of passing a limiter output through a low-pass filter.
FIG. 8 is a diagram showing a simulation result in which the operation of the multipath scan cell is verified.
FIG. 9 is a diagram illustrating a detailed configuration of a modified example of the multipath scan cell.
[Explanation of symbols]
18 Intermediate frequency amplifier circuit
20 DSP (digital signal processor)
22 Multipath Scancera
24 FM detection circuit
50, 51 Analog-digital (A / D) converter
52 Level fluctuation detector
54 Coefficient setting part
56 Multiplier
58 Subtraction part
60 Delay processing section
70 Hilbert transform filter
72, 74 square calculation unit
76 Adder
78 Square root operation section
80 limiter
82 Low-pass filter (LPF)
100 FM receiver

Claims (6)

Multipath interference of FM receiver comprising: multipath prediction means for predicting signal components caused by multipath interference; and signal removal means for removing signal components predicted by the multipath prediction means from an input intermediate frequency signal. In the removal device,
The multipath prediction means includes delay means for delaying the signal output from the signal removal means for a predetermined time, and level adjustment means for adjusting the level of the signal delayed by the delay means,
The level adjusting means includes a level fluctuation detecting means for detecting a fluctuation in the signal level of the intermediate frequency signal, and a gain for performing level adjustment according to the level fluctuation level detected by the level fluctuation detecting means. A gain setting means for setting the level of the signal after being delayed by the delay means, with the gain set by the gain setting means,
The level fluctuation detecting means includes a Hilbert transform filter that separates a real part and an imaginary part of the intermediate frequency signal, an arithmetic means that obtains a square root after obtaining a square sum of the real part and the imaginary part, and Limiting means for limiting the range of the output value by setting a predetermined upper limit value and lower limit value for the calculation result, and low-pass means for allowing only the low-frequency component to pass through the output value of the limiting means , Detecting the signal level based on the real part and the imaginary part,
It said limiting means, the multipath interference canceller of FM receiver, characterized in that you set variably according to the upper limit value and the lower limit to the average level of the intermediate frequency signal. Multipath interference of FM receiver comprising: multipath prediction means for predicting signal components caused by multipath interference; and signal removal means for removing signal components predicted by the multipath prediction means from an input intermediate frequency signal. In the removal device,
The multipath prediction means includes delay means for delaying the signal output from the signal removal means for a predetermined time, and level adjustment means for adjusting the level of the signal delayed by the delay means,
The level adjusting means includes a level fluctuation detecting means for detecting a fluctuation in the signal level of the intermediate frequency signal, and a gain for performing level adjustment according to the level fluctuation level detected by the level fluctuation detecting means. A gain setting means for setting the level of the signal after being delayed by the delay means, with the gain set by the gain setting means,
The level fluctuation detecting means includes a Hilbert transform filter that separates a real part and an imaginary part of the intermediate frequency signal, an arithmetic means that obtains a square root after obtaining a square sum of the real part and the imaginary part, and Limiting means for limiting the range of the output value by setting a predetermined upper limit value and lower limit value for the calculation result, and low-pass means for allowing only the low-frequency component to pass through the output value of the limiting means , Detecting the signal level based on the real part and the imaginary part,
Said limiting means on the basis of a signal output from said signal removal means, the multipath interference canceller of FM receiver characterized to settings which varies the upper limit value and the lower limit value. Multipath interference of FM receiver comprising: multipath prediction means for predicting signal components caused by multipath interference; and signal removal means for removing signal components predicted by the multipath prediction means from an input intermediate frequency signal. In the removal device,
The multipath prediction means includes delay means for delaying the signal output from the signal removal means for a predetermined time, and level adjustment means for adjusting the level of the signal delayed by the delay means,
The level adjusting means includes a level fluctuation detecting means for detecting a fluctuation in the signal level of the intermediate frequency signal, and a gain for performing level adjustment according to the level fluctuation level detected by the level fluctuation detecting means. A gain setting means for setting the level of the signal after being delayed by the delay means, with the gain set by the gain setting means,
The level fluctuation detecting means includes a Hilbert transform filter that separates a real part and an imaginary part of the intermediate frequency signal, an arithmetic means that obtains a square root after obtaining a square sum of the real part and the imaginary part, and Limiting means for limiting the range of the output value by setting a predetermined upper limit value and lower limit value for the calculation result, and low-pass means for allowing only the low-frequency component to pass through the output value of the limiting means , Detecting the signal level based on the real part and the imaginary part,
The limiting means variably sets the upper limit value and the lower limit value based on a result obtained by smoothing an absolute value of a signal output from the signal removal means, and multipath interference cancellation for an FM receiver apparatus. In any one of Claims 1-3,
The gain setting means selects one of a plurality of discrete gains prepared in advance within a range of 1 to 0 according to the level fluctuation level. Path interference canceller. In any one of Claims 1-4,
A multipath interference canceling apparatus for an FM receiver, wherein the multipath predicting means and the signal canceling means are realized by digital signal processing. In claim 5,
A multipath interference canceling apparatus for an FM receiver, wherein the digital signal processing is performed using a digital signal processing apparatus.

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