JP2004048397A - Reception system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reception system which can detect altogether noises of different characteristics included in an input signal by one detecting means, to perform appropriate signal processing according to the detected noises, to realize a smaller size system with cost reduction, and moreover, to perform noise detection with an accuracy higher than before. <P>SOLUTION: The reception system comprises a main signal line 20 which includes a frequency converting means 21 for converting an input signal to an IF (intermediate frequency) signal, an intermediate frequency processing means 23, and a demodulating means 24. The system is equipped with a noise detecting means 31 for processing the IF signal to detect noises, and a signal processing means 32 for performing signal processing for noise elimination according to the characteristics of each noise detected by the noise detecting means 31. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a receiving system, and more particularly, to a receiving system capable of removing noise included in an input signal.
[0002]
[Prior art]
In an in-vehicle receiving system, the electrical system pulse noise that occurs spontaneously when an electrical system switch such as a power window or wiper is operated, or the reflected wave reflected by a building or mountain interferes with the direct wave Multipath noise caused by changes in amplitude and phase, and radio waves with frequencies close to the selected frequency exist, and interference cannot be sufficiently eliminated by the selector in the receiving system. Interference noise and the like inevitably occur with changes in radio wave conditions and use environments, and various countermeasures against such noise have conventionally been taken.
[0003]
FIG. 17 is a block diagram schematically showing a main part of a conventional on-vehicle FM broadcast receiving system.
In the figure, reference numeral 50 denotes a receiving system, and a main signal line 60 of the receiving system 50
A front end section 61, an intermediate frequency amplification circuit section 62, a demodulation circuit section 63, and an MPX circuit 64 are arranged.
[0004]
The front end unit 61 includes a high-frequency amplifier circuit 61a, a local oscillator circuit 61b, and a mixer circuit 61c. The radio wave fetched from the antenna 51 is selectively amplified by the high-frequency amplifier circuit 61a, and the signal selectively amplified by the high-frequency amplifier circuit 61a and the local oscillation signal from the local oscillation circuit 61b are mixed by the mixer circuit 61b. (IF signal). The frequency conversion means 61d includes the local oscillation circuit 61b and the mixer circuit 61c.
[0005]
The IF signal from the mixer circuit 61c is output to an intermediate frequency amplifier circuit section 62 including a band limiter such as a band pass filter, is selected and amplified by the intermediate frequency amplifier circuit section 62, and is selected and amplified. The IF signal is output to the demodulation circuit unit 63, detected by the demodulation circuit unit 63, and demodulated into an audio signal before modulation. The demodulated audio signal is output to the MPX circuit 64 and, after being subjected to stereo demodulation, becomes LR output and is output as audio from a speaker (not shown).
[0006]
The intermediate frequency amplifying circuit 62 is connected to a multipath noise detecting circuit 74 and an interfering wave detecting circuit 75 via an envelope detector 71 and band pass filters (hereinafter, referred to as BPFs) 72 and 73. The output side of the multipath noise detection circuit 74 is connected to the MPX circuit 64, and the output side of the interference wave detection circuit 75 is connected to the intermediate frequency amplification circuit section 62.
[0007]
The demodulation circuit unit 63 is connected to a pulse noise detection circuit 77 via a high-pass filter (hereinafter, referred to as HPF) 76, and the output side of the pulse noise detection circuit 77 is connected to the demodulation circuit unit 63.
[0008]
Next, the operation of noise detection / removal processing in the conventional receiving system 50 will be described.
An envelope detector 71 connected to the intermediate frequency amplifier circuit 62 performs envelope detection of the IF signal. Thereafter, the detected signal is passed through a BPF 72 set to a predetermined bandwidth for multipath noise detection, thereby extracting a multipath noise detection signal.
[0009]
The multipath noise detection circuit 74 captures the extracted detection signal, detects multipath noise based on the captured detection signal, and converts the multipath noise detection signal to MPX when multipath noise is detected. Output to the circuit 64.
[0010]
The MPX circuit 64 changes the degree of separation between the L and R channels in the stereo sound based on the multipath noise detection signal. For example, the demodulated L and R stereo signals are added to create a monaural sound signal. Multipath noise is removed by performing processing for reducing the deterioration of the audio signal due to the influence of the path.
[0011]
Further, the signal detected by the envelope detection section 71 is passed through a BPF 73 set to a predetermined bandwidth for detecting the interference noise, thereby extracting the interference noise detection signal.
[0012]
The interference wave detection circuit 75 captures the extracted detection signal, detects an interference frequency signal near the desired frequency signal based on the captured detection signal, and, when the interference frequency signal is detected, The noise detection signal is output to the intermediate frequency amplifier circuit section 62.
[0013]
The intermediate frequency amplifying circuit 62 changes the bandwidth of a band limiter (not shown) to a narrower band based on the interference noise detection signal, and removes frequency components so as not to include interference noise. It is supposed to be.
[0014]
Further, the HPF 76 connected to the demodulation circuit unit 63 extracts a high-frequency component of the demodulated output, and outputs the extracted pulse noise detection signal to the pulse noise detection circuit 77.
[0015]
The pulse noise detection circuit 77 detects pulse noise based on the detection signal, and when the pulse noise is detected, for example, forms a switching pulse for specifying a noise generation section, and generates the switching pulse. The signal is sent to a switch circuit (not shown) included in the demodulation circuit unit 63.
[0016]
In the switch circuit, the demodulation output output from the demodulation circuit section 63 is cut off based on the switching pulse signal output from the pulse noise detection circuit 77, and for example, by holding the output level of the demodulation signal, Is removed.
[0017]
As described above, in the conventional receiving system 50 for a vehicle or the like, the pulse noise detection circuit 77 for removing the pulse noise, the multipath noise detection circuit 74 for detecting the multipath noise, and the interference noise are detected. And an interference wave detection circuit 75 and the like are provided independently of each other.
[0018]
[Problems to be solved by the invention]
However, the conventional receiving system 50 is configured to extract signals from points where noises are easily detected and detect them with different detection circuits for noises having different characteristics. It is necessary to provide a detection circuit for detecting the noise in accordance with each noise, so that the configuration of the receiving system is complicated and the cost is high.
[0019]
The present invention has been made in view of the above problems, and can detect all noises having different characteristics included in an input signal with one detection unit, and perform appropriate signal processing according to the detected noises. It is an object of the present invention to provide a receiving system that can reduce the size and cost of the system and can detect noise with higher accuracy than before.
[0020]
To achieve the above object, a receiving system (1) according to the present invention comprises: a frequency converting means for converting an input signal into an IF signal; an intermediate frequency processing means; Means for detecting noise by processing the IF signal, and removing noise in accordance with the characteristics of each noise detected by the noise detecting means. Signal processing means for performing signal processing for performing the following.
[0021]
According to the receiving system (1), the IF signal can be processed by the noise detection unit to detect noise having different characteristics included in the IF signal, and the noise characteristic can be reduced by the signal processing unit. Accordingly, signal processing for removing noise can be performed. Therefore, it is possible to integrate the detection circuits conventionally provided individually corresponding to respective noises such as pulse noise, multipath noise, and interference noise into one, and to constitute an element or signal constituting the noise detection means. The number of operations in the processing can be reduced, and the size and cost of the system can be reduced.
Further, by extracting a signal for detecting noise from the high-band side of the IF signal, and by making all noise detection points the same, noise detection sensitivity can be increased, and highly accurate noise detection can be performed. Can be.
[0022]
Also, in the receiving system (2) according to the present invention, in the receiving system (1), the signal processing unit may determine a type of noise based on a detection result of the noise detecting unit; Control signal output means for outputting a control signal for causing noise removal according to the type of noise determined by the means to predetermined noise removal means.
[0023]
According to the reception system (2), the type of noise can be accurately determined by the noise determination unit, and the control signal corresponding to the determined type of noise is output to the predetermined noise removal unit. Thus, it is possible to accurately remove the detected noise.
[0024]
Further, a receiving system (3) according to the present invention is characterized in that, in said receiving system (2), said noise detecting means uses FFT processing of said IF signal.
[0025]
According to the receiving system (3), since the noise detection unit uses the FFT processing of the IF signal, the level of each frequency component included in the IF signal can be obtained by the FFT processing. . As a result, the noise included in the IF signal can be easily detected from the level change, and the type of the noise can be easily determined from the difference in the level characteristics.
[0026]
Further, a receiving system (4) according to the present invention is characterized in that in any one of the above-mentioned receiving systems (1) to (3), a band limiting unit is provided at a stage preceding the noise detecting unit.
[0027]
According to the receiving system (4), since the band limiting unit is provided in front of the noise detecting unit, a band component unnecessary for noise detection can be removed by the band limiting unit in advance. As a result, erroneous detection of noise can be prevented. As the band limiting means, an element such as a ceramic filter, or a device configured as a band pass filter using a digital filter or the like can be employed.
[0028]
Further, a receiving system (5) according to the present invention is characterized in that, in said receiving system (4), said band limiting means is also used as that included in said main signal line.
[0029]
According to the receiving system (5), since the band limiting unit is also used for the one included in the main signal line, it is not necessary to newly provide the band limiting unit, and without adding cost. It is possible to efficiently prevent erroneous detection of noise.
[0030]
Further, in the receiving system (6) according to the present invention, in the above-mentioned receiving system (1) or (2), the noise detection unit is configured to include a plurality of filter units having a specific limited band connected in parallel. It is characterized by having.
[0031]
According to the receiving system (6), it is possible to accurately detect noise by separately setting the limited bands of the plurality of filter means in advance according to the frequency characteristics of the noise to be removed. Become. Therefore, it is possible to easily determine the type of noise from each output signal of the plurality of filter means.
[0032]
Further, in the receiving system (7) according to the present invention, in the receiving system (3), the noise discriminating unit monitors a level of each frequency component of the IF signal subjected to the FFT processing; Level storage means for storing a level of a specific frequency component of the IF signal monitored by the first monitoring means; and a change in a temporal level of the specific frequency component of the IF signal stored in the level storage means. And a second monitoring unit for monitoring, wherein a type of noise is determined based on a monitoring result of the first monitoring unit and the monitoring result of the second monitoring unit.
[0033]
According to the receiving system (7), the noise determination unit can accurately determine the type of noise based on the monitoring results of the first monitoring unit and the second monitoring unit.
[0034]
In the reception system (8) according to the present invention, in the reception system (3) or (7), the noise detection unit further includes a phase detection unit that detects a phase of the IF signal; The type of noise is determined based on the phase detection data detected by the phase detection means.
[0035]
According to the receiving system (8), the FFT processing and the phase detection can be used for noise detection, and are particularly effective means in a frequency modulation system. That is, the phase detection means acts as a demodulator, and a noise component can be extracted by passing the output through a band-pass filter of a specific band. Therefore, the noise can be accurately determined by combining the FFT processing data and the noise information of the phase detection signal processed by the phase detection means, and the noise detection accuracy and the noise determination accuracy are improved. Can be enhanced.
[0036]
A receiving system (9) according to the present invention is characterized in that, in the receiving system (8), the phase detecting means is also used as the one included in the demodulating means.
[0037]
According to the receiving system (9), since the phase detection means is also used as the one included in the demodulation means, it is not necessary to newly provide the phase detection means in the system, thereby preventing an increase in cost. However, substantially the same effects as those of the receiving system (8) can be obtained.
[0038]
Also, the receiving system (10) according to the present invention, in any one of the receiving systems (2) to (9), further includes a bandwidth limiting unit in the main signal line, wherein the control signal output unit includes the variable bandwidth limiting unit. An output of a zero complement control signal for zero complementing a noise generation portion of a demodulated output from the demodulator, and / or a bandwidth change control signal for changing the bandwidth of the band limiter with respect to the band limiter. Is performed according to the type of noise.
[0039]
According to the receiving system (10), it is possible to perform zero complementation on a portion where the noise of the demodulation output is generated. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output. The band limiting means can be realized by narrowing the band by using an element such as a ceramic filter, a digital filter, or the like arranged in the main signal line.
[0040]
Also, the reception system (11) according to the present invention, in any one of the reception systems (2) to (9), further includes a band-limiting unit configured to vary a bandwidth in the main signal line, and the control signal output unit includes the control signal output unit. An output of a pre-completion control signal for pre-complementing a noise generation portion of the demodulation output from the demodulation means, and / or a bandwidth change for changing the bandwidth of the band-limiting means to the band-limiting means It is characterized in that the control signal is output in accordance with the type of noise.
[0041]
According to the receiving system (11), it is possible to pre-complement the occurrence location of the noise of the demodulated output, and for example, it is possible to remove pulse noise and multipath noise by pre-complementation. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output.
[0042]
Further, the receiving system (12) according to the present invention, in any one of the receiving systems (2) to (9), further includes a bandwidth limiting unit in the main signal line, the control signal output unit comprising: The output of a linear complement control signal for linearly complementing the demodulated output from the demodulator and / or the output of the bandwidth change control signal for changing the bandwidth of the band limiter to the band limiter are noise. It is characterized in that it is performed according to the type of.
[0043]
According to the receiving system (12), it is possible to linearly complement a portion where the noise of the demodulation output is generated, and for example, it is possible to remove pulse noise and multipath noise by linear complementation. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output.
[0044]
The receiving system (13) according to the present invention, in any one of the receiving systems (2) to (9), includes a band-limiting means for varying a bandwidth, and a demodulation output storage means for storing a demodulation output from the demodulation means. Prediction output creating means for predicting and creating a normal demodulation output in a noise generation section based on the demodulation output stored in the demodulation output storage means, and a prediction output in place of the noise generation section in place of the demodulation output. Predictive output switching means for switching, wherein the control signal output means outputs the predicted output switching control signal to the predictive output switching means and / or the bandwidth of the band limiting means to the band limiting means Is output according to the type of noise.
[0045]
According to the receiving system (13), the noise generation section of the demodulated output can be switched to the predicted output, and for example, pulse noise and multipath noise can be removed. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output.
[0046]
Further, the receiving system (14) according to the present invention, in any one of the receiving systems (2) to (9), further comprises: a band-limiting unit having a variable bandwidth on the main signal line; Wherein the control signal output means outputs a stereo separation degree control signal for changing the stereo separation degree to the MPX circuit, and / or the bandwidth of the band limitation means to the band limitation means. It is characterized in that the output of the bandwidth change control signal for changing is performed according to the type of noise.
[0047]
According to the receiving system (14), by changing the MPX circuit so that the stereo separation degree is attenuated, for example, it is possible to particularly reduce the noise feeling of multipath noise. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output.
[0048]
Further, a receiving system (15) according to the present invention, in any one of the receiving systems (2) to (9), further comprising: a bandwidth limiting unit configured to vary a bandwidth in the main signal line; Outputting a mute control signal for muting the demodulated output from the demodulating means and / or outputting a bandwidth change control signal for changing the bandwidth of the band limiting means to the band limiting means; Is performed in accordance with the type of noise.
[0049]
According to the receiving system (15), it is possible to mute the noise generation portion of the demodulated output, and it is possible to alleviate the noise such as pulse noise and multipath noise. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output.
[0050]
Further, a receiving system (16) according to the present invention, in any one of the receiving systems (2) to (9), further comprising: a bandwidth limiting unit in the main signal line, the control signal output unit comprising: An output of a frequency characteristic control signal for attenuating a high frequency in a demodulation output from the demodulation means and / or an output of a bandwidth change control signal for changing the bandwidth of the band limiting means to the band limiting means. Is performed in accordance with the type of noise.
[0051]
According to the receiving system (16), by attenuating the high frequency in the demodulated output, it is possible to alleviate the noise such as pulse noise and multipath noise. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and a control signal suitable for the type of noise can be output.
[0052]
Further, the receiving system (17) according to the present invention, in any one of the receiving systems (2) to (9), further comprises a band limiting unit for changing a bandwidth in the main signal line, and An output of a zero complement control signal for causing the intermediate frequency processing means to perform zero complementation of a noise generation portion of the IF signal, and / or a bandwidth for changing a bandwidth of the band limiting means for the band limiting means. The output of the change control signal is performed according to the type of noise.
[0053]
According to the receiving system (17), the intermediate frequency processing means can remove pulse noise and multipath noise in the IF signal by zero complementation. Since the noise in the intermediate frequency processing means has a narrower temporal spread than the noise of the demodulated output, the time required for noise removal can be reduced as compared with the case where the demodulated output is similarly complemented. In particular, it is effective in amplitude modulation applications such as AM radio. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and output processing of a control signal suitable for the type of noise can be performed.
[0054]
Further, a receiving system (18) according to the present invention, in any one of the receiving systems (2) to (9), further includes a band-limiting unit configured to vary a bandwidth in the main signal line, and the control signal output unit includes: An output of a pre-completion control signal for pre-complementing a noise generation point of the IF signal to the intermediate frequency processing means, and / or changing a bandwidth of the band restriction means to the band restriction means. It is characterized in that the output of the bandwidth change control signal is performed according to the type of noise.
[0055]
According to the receiving system (18), the intermediate frequency processing means can remove pulse noise and multipath noise in the IF signal by performing prefix complementation, and have substantially the same effect as the receiving system (17). Obtainable. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and output processing of a control signal suitable for the type of noise can be performed.
[0056]
Further, a receiving system (19) according to the present invention, in any one of the receiving systems (2) to (9), further comprising a bandwidth limiting unit for changing a bandwidth in the main signal line, An output of a linear complement control signal for linearly complementing a noise generation point of the IF signal to the intermediate frequency processing unit, and / or a bandwidth for changing the bandwidth of the band limiting unit to the band limiting unit The output of the change control signal is performed according to the type of noise.
[0057]
According to the receiving system (19), pulse noise and multipath noise in the IF signal in the intermediate frequency processing means can be removed by linear interpolation, and substantially the same effects as those of the receiving system (17) can be obtained. Can be. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, interference noise can be removed, and output processing of a control signal suitable for the type of noise can be performed.
[0058]
The receiving system (20) according to the present invention is the receiving system according to any one of the receiving systems (2) to (9), further comprising: an IF signal for storing an IF signal from the intermediate frequency processing unit. Storage means, prediction output creating means for predicting and creating a normal IF signal in a noise occurrence section based on the IF signal stored in the IF signal storage means, and predicting the noise occurrence section in place of the IF signal Predictive output switching means for switching to an output, wherein the control signal output means outputs a predictive output switching control signal to the predictive output switching means and / or a band of the band limiting means to the band limiting means. It is characterized in that a bandwidth change control signal for changing the width is output according to the type of noise.
[0059]
According to the reception system (20), the section in which the IF signal noise occurs in the intermediate frequency processing means can be switched to the prediction output, and pulse noise and multipath noise can be removed. Further, since the noise in the intermediate frequency processing means has a narrower temporal spread than the noise of the demodulated output, it is possible to reduce the time required for the predicted output as compared with switching the demodulated output to the predicted output. Further, by changing the bandwidth of the band limiting unit to, for example, a narrow band, it is possible to remove the interference noise, and it is possible to output an appropriate control signal corresponding to the type of the noise.
[0060]
Also, the reception system (21) according to the present invention is determined by the noise determination unit from the processing performed by the control signal output unit according to any one of the reception systems (10) to (20). It is characterized in that three or more types of processing are used in combination according to the characteristics and types of noise.
[0061]
According to the reception system (21), various signal processing combinations can be performed according to the determined noise, and appropriate signal processing can be performed according to the characteristics and types of the noise. For example, if the determined noise is pulse noise, a control signal is output so as to pre-complement the noise generation location of the demodulated output, or if the noise is multipath noise, A control signal is output to the MPX circuit so as to change the degree of stereo separation, or when the noise is interference noise, the bandwidth is changed to a narrow band by the band limiting means. As described above, the control signal can be output, and by performing signal processing suitable for the determined noise, the SN ratio of the receiving system can be further improved.
[0062]
The receiving system (22) according to the present invention, in any one of the receiving systems (1) to (9), further includes an electric field intensity monitoring unit that monitors an electric field intensity of a received radio wave, and the noise determination unit includes the electric field intensity monitoring unit. When the electric field intensity monitored by the intensity monitoring means is equal to or lower than a predetermined level, a noise judgment interruption means for interrupting the noise judgment is provided.
[0063]
When the electric field strength is reduced, it is difficult to distinguish between the signal and the noise due to the white noise, the detection accuracy of the noise is reduced, and the possibility of erroneous noise determination is increased. Therefore, according to the receiving system (22), when the electric field strength is equal to or lower than the predetermined level, the noise determination is interrupted so that the noise is not removed, thereby preventing the malfunction of the noise removing operation. Can be.
[0064]
The receiving system (23) according to the present invention, in any one of the receiving systems (1) to (9), further includes an electric field intensity monitoring unit that monitors an electric field intensity of a received radio wave, and the noise discriminating unit includes the electric field intensity monitoring unit. A noise detection sensitivity changing means for changing the noise detection sensitivity according to the electric field intensity monitored by the intensity monitoring means is provided.
[0065]
According to the receiving system (23), the noise detection sensitivity changing unit changes the noise detection sensitivity according to the electric field intensity. For example, when the electric field strength decreases, the noise detection sensitivity can be reduced to improve the accuracy of the noise determination, thereby preventing a malfunction in the noise removing operation when the electric field strength decreases.
[0066]
The receiving system (24) according to the present invention, in any one of the receiving systems (2) to (9), further includes a filter unit as the noise removing unit in the main signal line, and the control signal output unit includes: It is characterized in that the filter means outputs a filter coefficient change control signal so as to change to an appropriate filter coefficient according to the characteristics and type of the determined noise.
[0067]
According to the receiving system (24), the noise can be removed and suppressed by changing the filter coefficient of the filter means according to the characteristics and type of the determined noise. Therefore, the hardware configuration of the system can be simplified, and the filter coefficient can be changed, so that it is possible to flexibly deal with detected noise. In addition, it is preferable that the filter means performs processing using a digital signal processor or the like which can be configured as software in order to change the coefficient.
[0068]
The receiving system (25) according to the present invention, in the receiving system (24), further includes a filter coefficient storing unit that stores a filter coefficient corresponding to a characteristic and a type of noise. An appropriate filter coefficient is read out from the filter coefficients stored in the filter coefficient storage means based on a control signal, and the filter coefficient is switched to the filter coefficient to remove noise.
[0069]
According to the receiving system (25), since the filter coefficients are stored in the filter coefficient storage unit, it is not necessary to calculate the filter coefficients by calculation each time, and the processing can be reduced.
[0070]
Further, in the receiving system (26) according to the present invention, in the receiving system (25), when the filter coefficients stored in the filter coefficient storing means cannot be used, the filter coefficient calculating means for calculating the optimum filter coefficient by the calculation is provided. And a filter coefficient update storage means for updating and storing the filter coefficient obtained by the filter coefficient calculation means in the filter coefficient storage means.
[0071]
According to the receiving system (26), when the filter coefficient stored in advance cannot be used, the optimum filter coefficient is obtained by calculation and sequentially updated and stored, so that it can cope with various noises having different characteristics. This makes it possible to perform the setting of the filter coefficient, thereby improving the noise removing function of the filter means.
[0072]
Further, a receiving system (27) according to the present invention, in any one of the receiving systems (2) to (9), further includes a filter unit as the noise removing unit on the main signal line, wherein the filter unit includes a plurality of filter units. The control signal output means changes the filter means so that the filter means has an appropriate filter configuration according to the characteristics and type of the determined noise. It is characterized by outputting a filter configuration change control signal.
[0073]
According to the receiving system (27), noise can be removed and suppressed by changing the configuration of the plurality of filter units constituting the filter unit in accordance with the characteristics and type of the determined noise. Therefore, the hardware configuration of the system can be simplified, and the filter configuration can be changed, so that it is possible to flexibly cope with detected noise. In order to change the configuration of the filter means, it is preferable to perform processing using a digital signal processor or the like which can be configured as software.
[0074]
The receiving system (28) according to the present invention, in any one of the receiving systems (2) to (9), includes a diversity unit that selects a large output signal from a plurality of antenna outputs for the main signal line. Wherein the control signal output means outputs an antenna selection control signal for selecting an adopted antenna to the diversity means.
[0075]
According to the receiving system (28), the control signal output unit outputs an antenna selection control signal for selecting an adopted antenna to the diversity unit. The adopted antenna can be selected based on the antenna selection control signal. For example, when multipath noise is detected, the adopted antenna can be appropriately selected, and the intrusion of the multipath noise into the receiving system can be reduced. Can be prevented.
[0076]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of a receiving system according to the present invention will be described with reference to the drawings. FIG. 1 is a block diagram schematically showing a main part of a receiving system according to Embodiment (1).
[0077]
In the figure, reference numeral 10 denotes a receiving system, and a main signal line 20 of the receiving system 10 is connected to a front end unit 21, a delay unit 22, an intermediate frequency amplifier circuit unit 23, and a demodulation circuit unit 24. The output side of the front end unit 21 is connected to an FFT processing unit 31 that branches and forms a noise detection unit, a noise determination unit 33 and a control signal output unit 34 that form a signal processing unit 32, and a control signal output unit. The output side of 34 is connected to the intermediate frequency amplification circuit section 23 and the demodulation circuit section 24. Further, a memory 35 is connected to the FFT processing section 31 so that predetermined FFT processing data is stored.
[0078]
The front end unit 21 includes a high-frequency amplifier circuit, a local oscillator circuit, and a mixer circuit (none of which are shown), and selectively (tunes) and amplifies a radio wave taken in from the antenna 11 and selectively amplifies the radio wave. The signal and the local oscillation signal are mixed by a mixer circuit to generate an intermediate frequency signal (IF signal). Frequency conversion means includes a local oscillation circuit and a mixer circuit.
[0079]
The delay unit 22 considers the signal processing time in the FFT processing unit 31, the noise determination unit 33, and the control signal output unit 34, and performs an IF signal to the intermediate frequency amplification circuit unit 23 so that noise can be removed at an accurate timing. , And is constituted by a delay circuit or the like.
[0080]
The intermediate frequency amplifying circuit unit 23 includes a BPF 23a, which is a band limiter having a variable bandwidth. The IF signal from the delay unit 22 is selectively extracted as a signal of a predetermined frequency band by the BPF 23a. The passed signal is amplified to a predetermined level.
[0081]
The demodulation circuit section 24 detects the IF signal selected and amplified by the intermediate frequency amplification circuit section 23 and demodulates the IF signal into an unmodulated audio signal. The 0 complementation output from the control signal output section 34 is provided. It is configured to include a 0 complementation processing unit 24a that complements the noise generation section of the demodulation output with 0 based on the control signal. The 0 complementation processing unit 24a is configured to include a switch circuit and the like. The demodulated output after the noise removal processing is output as a sound from a speaker (not shown) or the like.
[0082]
The FFT processing unit 31 fetches an IF signal from the front end unit 21, performs high-speed Fourier transform processing of the IF signal, and calculates the level of the IF signal in a predetermined frequency band, and includes a digital signal processor and the like. The level of the IF center frequency (10.7 MHz for FM broadcast, 455 kHz for AM broadcast) among the calculated data is monitored and sequentially stored in the memory 35. .
[0083]
The noise determination unit 33 performs a process of determining the type of noise included in the IF signal based on the level of the IF signal subjected to the FFT processing by the FFT processing unit 31, and the noise determination process will be described later. I do.
[0084]
The control signal output unit 34 controls the operation of the noise removing unit (in this embodiment, the BPF 23a and the 0 complementation processing unit 24a) that removes the determined noise after the noise type is determined by the noise determination unit 33. In the present embodiment, when a pulse noise and / or a multipath noise is detected, 0 is supplied to the 0 complementation processing unit 24a of the demodulation circuit unit 24. Outputs a complementary control signal. When the interference noise is detected, a bandwidth change control signal for changing the pass bandwidth to a narrow band is output to the BPF 23a of the intermediate frequency amplifier circuit unit 23, and the BPF 23a outputs the bandwidth change control signal. , The bandwidth is changed to a narrow band so that the frequency component of an adjacent interference wave which becomes interference noise is not passed.
[0085]
Next, a method for detecting and discriminating noise using FFT processing in the receiving system according to Embodiment (1) will be described.
FIG. 2A shows the signal waveform of the IF signal including the pulse noise, and at time t. ₁ And t ₂ 5 and 6 show a state in which pulse noise is generated. FIG. 2B shows the signal waveform of the demodulated output at that time.
[0086]
FIG. 2C shows a time T during which no pulse noise is generated in FIG. ₁ The data (data A) obtained by subjecting the IF signal of (10 μs) to FFT processing and the time T during which pulse noise is generated ₂ (Data B) obtained by subjecting the IF signal of (10 μs) to FFT processing.
[0087]
In data A in a section where no pulse noise occurs, an energy distribution having a peak at the IF intermediate frequency is detected. On the other hand, in the data B in the section where the pulse noise is generated, there is no peak at the IF intermediate frequency unlike the data A, and the frequency component of the pulse noise is added to each frequency component of the IF signal. As a result, an energy distribution in which the signal level becomes high over a wide band is detected.
[0088]
As described above, when the FFT processing of the IF signal detects energy distribution data such as data B in which the signal level increases over a wide band, it is determined that pulse noise has occurred. it can.
[0089]
FIG. 3A shows a signal waveform of an IF signal including multipath noise, and is shown at time t. ₁₁ , T ₁₂ , T ₁₃ And t ₁₄ Shows a state in which multipath noise is occurring. FIG. 3B shows the signal waveform of the demodulated output at that time.
[0090]
In FIG. 3C, the time T during which no multipath noise occurs in FIG. ₁₁ IF signal ₁₂ (Data D) obtained by subjecting the IF signal to FFT processing.
[0091]
In data C in a section where no multipath noise is generated, an energy distribution having a peak at the IF center frequency is detected as in data A in FIG. On the other hand, in the data D in the section where the multipath noise is generated, although an energy distribution having a peak at the IF center frequency is detected, the signal level of the frequency band including the IF center frequency is not detected. Energy distribution data that is much lower than data C is detected.
[0092]
As described above, when FFT processing of the IF signal detects energy distribution data such as data D in which the signal level of the IF center frequency sharply drops, multipath noise is generated. Can be determined.
[0093]
FIG. 4 shows data obtained by performing FFT processing on an IF signal when interference noise is occurring. An energy distribution is detected in which a peak of an adjacent interfering frequency steadily exists near the IF intermediate frequency of a desired frequency.
[0094]
As described above, as a result of the FFT processing of the IF signal, when energy distribution data having a different peak near the peak of the IF center frequency of the desired frequency is continuously detected for a predetermined time, It can be determined that interference noise has occurred.
[0095]
Next, the operation of the noise discrimination / removal processing in the receiving system according to the embodiment (1) will be described based on the flowchart shown in FIG. The noise discrimination by the present noise discrimination / removal processing operation is performed every time the FFT processing unit 31 samples the IF signal.
[0096]
First, in step S1, the noise discriminating section 33 fetches FFT processing data of the IF signal from the FFT processing section 31 (first monitoring processing), and then proceeds to step S2. In step S2, it is determined whether or not a peak occurs at a predetermined frequency of the FFT processing data. If it is determined that no peak has occurred at a predetermined frequency, the process proceeds to step S11. On the other hand, if it is determined that a peak occurs at a predetermined frequency, the process proceeds to step S3.
[0097]
In step S3, it is determined whether or not the frequency at which the peak occurs is within the selected reception band. If it is determined that the frequency is not within the reception band, that is, outside the reception band, the process proceeds to step S4.
[0098]
In step S4, it is determined whether or not the peak amplitude level is equal to or greater than a predetermined value set in order to determine whether or not the noise is noise. If so, the process proceeds to step S5.
[0099]
In step S5, monitoring processing of FFT processing data (second monitoring processing) is performed, and the flow advances to step S6. For example, if the sampling of the IF signal in the FFT processing unit 31 is performed in 1 μs and the generation time of the pulse noise included in the IF signal is set to 0.5 μs, the sampling may be performed at least twice.
[0100]
In step S6, it is determined whether or not the amplitude level of the peak of the sampled FFT processing data has become equal to or less than a specified value. If the amplitude level has become equal to or less than the specified value, that is, pulse noise has been detected. If so, the process proceeds to step S7. In step S7, a process of outputting a pulse noise discrimination signal to the control signal output unit 34 is performed, and then the process proceeds to step S8.
[0101]
In step S8, the control signal output unit 34 outputs a zero complement control signal to the zero complement processing unit 24a of the demodulation circuit unit 24, and ends the processing. Thereafter, the 0 complementation processing section 24a of the demodulation circuit section 24 performs 0 complementation processing of the demodulated output in the noise generation section based on the 0 complementation control signal, and outputs a demodulated signal from which the pulse noise portion has been removed.
[0102]
On the other hand, if it is determined in step S3 that the frequency at which the peak occurs is within the receiving band, that is, it is determined that the frequency is the IF intermediate frequency of the desired station and is not noise, the processing is terminated.
On the other hand, if it is determined in step S4 that the peak amplitude level is not equal to or greater than the specified value, the process is thereafter terminated.
[0103]
On the other hand, if it is determined in step S6 that the amplitude level remains at or above the specified value, that is, it is determined that interference noise has been detected, the process proceeds to step S9. In step S9, a process of outputting the interference noise determination signal to the control signal output unit 34 is performed, and then the process proceeds to step S10.
[0104]
In step S10, the control signal output unit 34 outputs a bandwidth change control signal for narrowing the bandwidth to the BPF 23a of the intermediate frequency amplifier circuit unit 23, and ends the processing. Thereafter, in the intermediate frequency amplifying circuit section 23, the bandwidth of the BPF 23a is changed to be narrow, and the IF signal from which the frequency component serving as interference noise has been removed is amplified.
[0105]
On the other hand, if it is determined in step S2 that no peak occurs at a predetermined frequency, the process proceeds to step S11. In step S11, it is determined whether or not the level of the center frequency of the IF signal has changed. If it is determined that the level of the intermediate frequency of the IF signal has changed, the process proceeds to step S12. On the other hand, if it is determined that the level of the intermediate frequency of the IF signal has not changed, the process ends.
[0106]
In step S12, a process of calculating the level fluctuation amount of the center frequency of the IF signal is performed, and then the process proceeds to step S13. In step S13, it is determined whether or not the level fluctuation amount is equal to or greater than a specified value. In step S14, a process of outputting a multipath noise determination signal to the control signal output unit 34 is performed, and then the process proceeds to step S15.
[0107]
In step S15, the control signal output unit 34 outputs a zero complement control signal to the zero complement processing unit 24a of the demodulation circuit unit 24, and ends the processing. Thereafter, the 0 complementation processing unit 24a of the demodulation circuit unit 24 performs a 0 complementation process on the demodulated output of the multipath noise generation section based on the 0 complementation control signal, and outputs a demodulated signal with the multipath noise generation section complemented by 0. Is output.
[0108]
On the other hand, if it is determined in step S13 that the level fluctuation amount is not equal to or greater than the specified value, it is determined that the fluctuation of the electric field intensity is not noise, and then the processing is terminated.
[0109]
According to the receiving system according to the first embodiment, the level of each frequency component constituting the IF signal can be obtained by performing the FFT processing on the IF signal by the FFT processing unit 31. As a result, it is possible to easily detect all noises included in the IF signal from the change in the level characteristics.
In addition, the type of noise can be accurately determined by the noise determination unit 33, and a control signal can be output to the BPF 23a or the zero complement processing unit 24a according to the determined type of noise. Can be accurately performed, and appropriate signal processing for performing noise removal according to noise characteristics is performed by the signal processing unit 32 including the noise determination unit 33 and the control signal output unit 34. be able to.
Therefore, it is possible to integrate the noise detection circuits conventionally provided individually corresponding to respective noises such as pulse noise, multipath noise, and interference noise into one, and the elements or signals constituting the noise detection circuit can be integrated. The number of operations in the processing can be reduced, and the size and cost of the system can be reduced.
[0110]
In addition, by extracting a signal for detecting noise from the high band side of the IF signal and setting the same noise detection point, noise detection sensitivity can be increased, and highly accurate noise detection can be performed.
[0111]
In the first embodiment, when it is determined that pulse noise or multipath noise is included, the control signal output unit 34 outputs the zero complement control signal to the zero complement process of the demodulation circuit unit 24. Although it is configured to output to the unit 24a, in another embodiment, a pre-complementary processing unit that performs a process of complementing a noise generation section with a signal immediately before noise generation is provided in the demodulation circuit unit 24, The control signal output unit 34 causes the pre-completion processing unit to output a pre-completion control signal for performing a pre-compensation process with the demodulated signal immediately before the noise generation, or causes the demodulation circuit unit 24 to generate a noise. A linear complement processing unit is provided for performing a process of complementing a section with a signal connecting the front and rear of the section with a straight line, and the control signal output unit 34 causes the linear complement processing unit to linearly complement the demodulated output. Linear complement of It can also be adapted to output a control signal.
[0112]
When a soft mute circuit (not shown) is provided on the output side of the demodulation circuit section 24, the control signal output section 34 outputs the pulse noise discrimination signal output from the noise discrimination section 33 or the multipath signal. A soft mute control signal is output to the soft mute circuit based on the noise discrimination signal, and the soft mute circuit performs a soft mute process on a demodulated output in a noise generation section. It can also reduce the feeling.
[0113]
Alternatively, when a high-cut circuit (not shown), which is high-frequency attenuating means, is provided on the output side of the demodulation circuit section 24, the control signal output section 34 outputs the pulse transmitted from the noise determination section 33. Based on a noise discrimination signal or a multipath noise discrimination signal, a frequency characteristic control signal for attenuating a high band is output to the high cut circuit, so that the high cut circuit outputs a high band of a demodulated output in a noise generation section. The output level of the portion can be attenuated to reduce noise.
[0114]
Further, when an MPX circuit is provided on the output side of the demodulation circuit section 24, the control signal output section 34 outputs a signal to the MPX circuit based on the multipath noise determination signal output from the noise determination section 33. By outputting a stereo separation control signal in the MPX circuit, stereo broadcasting can be switched to monaural broadcasting in the MPX circuit, or the degree of noise can be reduced by changing the degree of stereo separation by adjusting the degree of monaural. it can.
[0115]
Further, a demodulation output storage means for storing a demodulation output at a stage subsequent to the demodulation circuit section 24, and a prediction for predicting and producing a normal demodulation output in a noise generation section based on the demodulation output stored in the demodulation output storage means. If the receiving system further includes an output creation unit and a prediction output switching unit that switches the noise generation section to a prediction output instead of the demodulation output, the control signal output unit 34 is transmitted from the noise determination unit 33. Based on the incoming pulse noise discrimination signal or multipath noise discrimination signal, a prediction output switching control signal is output to the prediction output switching means, and the demodulation output of the noise generation section is switched to the created prediction output. , Can also remove noise. The prediction output creating means can be constituted by an adaptive filter or the like.
[0116]
FIG. 6 is a block diagram schematically showing a main part of the receiving system according to Embodiment (2). However, the configuration of the receiving system 10A according to the embodiment (2) is substantially the same as that of the receiving system 10 shown in FIG. 1 except that the BPF 36 is provided in a stage preceding the FFT processing unit 31. The BPF 36 is denoted by a different reference numeral, and the other components having the same function are denoted by the same reference numeral, and the description thereof will be omitted.
[0117]
In the receiving system 10A, a BPF 36 is newly provided before the FFT processing unit 31 by branching from the output side of the front end unit 21. The BPF 36 can be configured using, for example, an element such as a ceramic filter or a digital filter, and the pass band of the BPF 36 is set to a band capable of removing a band component unnecessary for noise detection. ing. For example, it is possible to set a predetermined pass band around the IF intermediate frequency so that the reception band of the FM broadcast can be narrowed down to the reception band of the FM broadcast when receiving the FM broadcast and the reception band of the AM broadcast can be narrowed down when the AM broadcast is received. it can.
[0118]
According to the receiving system according to the embodiment (2), since the BPF 36 is provided in a stage preceding the FFT processing unit 31, band components unnecessary for noise detection by the BPF 36 are removed before performing the FFT processing. Erroneous detection of noise can be prevented.
[0119]
In the receiving system according to the above-described embodiment (2), the BPF 36 is newly provided in a stage preceding the FFT processing unit 31. However, in another embodiment, the intermediate frequency amplifying circuit unit 23 is configured. The BPF 23a may be arranged between the front end unit 21 and the delay unit 22 so that the output side of the BPF 23a is branched so that the IF signal passing through the BPF 23a can be taken into the FFT processing unit 31. According to such a configuration, it is not necessary to newly add the BPF 36 to the system, and it is possible to prevent an increase in cost.
[0120]
For example, when the present invention is applied to an FM broadcast receiving system, a ceramic filter having a bandwidth of about 200 kHz constituting the intermediate frequency amplifying circuit section 23 is disposed between the front end section 21 and the delay section 22 to form a BPF 23a. By diverting, similar to the receiving system 10A according to the embodiment (2), a frequency band unnecessary for noise detection can be removed before noise detection, and erroneous noise detection can be prevented.
[0121]
FIG. 7 is a block diagram schematically showing a main part of a receiving system according to Embodiment (3). However, the configuration of the receiving system 10B according to the embodiment (3) is substantially the same as the receiving system 10 shown in FIG. 1 except for the phase detecting unit 37 and the BPF 38, so that the phase detecting unit 37 having a different function is used. , The BPF 38 and the noise discriminating unit 33A are denoted by different reference numerals, and other components having the same function are denoted by the same reference numerals, and description thereof will be omitted.
[0122]
The receiving system 10B according to the embodiment (3) is different from the receiving system 10 according to the embodiment (1) in that the FFT processing unit 31 branches from the main signal line 20 to the output side of the front end unit 21. And the phase detection unit 37 are connected to each other, and a noise detection unit is configured to include the FFT processing unit 31 and the phase detection unit 37. It is assumed that the receiving system 10B is adopted as a receiving system for FM broadcasting.
[0123]
The phase detection unit 37 that detects the amplitude of the IF signal has a role as a demodulator, and passes the output signal through a BPF 38 having a specific band, for example, a frequency band around 100 kHz, thereby detecting the extracted signal. Noise components can be extracted from the signal.
[0124]
The noise discriminating section 33A discriminates the type of noise based on the FFT processing data in the FFT processing section 31 and the signal data processed by the phase detecting section 37 and the BPF 38.
[0125]
Next, a description will be given, based on a flowchart shown in FIG. 8, of a noise discriminating / removing operation in the receiving system according to the embodiment (3). Note that this noise discrimination / removal processing operation has a configuration in which steps S21 and S22 are inserted instead of step S4 in FIG. 5, and only the differences will be described below.
[0126]
If it is determined in step S3 that the frequency at which the peak occurs is not within the selected reception band, that is, outside the reception band, the process proceeds to step S21.
[0127]
In step S21, the peak amplitude level is determined. In this case, there are three levels of levels for determination, that is, a level range A in which noise can be determined only by FFT processing data, and a boundary level range B in which accurate determination of noise is difficult only by FFT processing data. , And a level range C in which it can be determined that there is no noise only by the FFT processing data. If it is determined in step S21 that the peak amplitude level is within the level range A, the process proceeds to step S5 and subsequent steps.
[0128]
If it is determined that the peak amplitude level is within the level range C, the process ends. Then, if it is determined that the peak amplitude level is within the boundary level range B, that is, the boundary level is such that it is difficult to accurately determine the noise using only the FFT processing data, the process proceeds to step S22.
[0129]
In step S22, it is determined whether or not noise has been detected in the phase detection signal captured via the phase detection unit 37 and the BPF 38. If it is determined that noise has been detected, the process proceeds to step S5 and the subsequent steps. If it is determined in S22 that noise has not been detected, the process ends.
[0130]
According to the receiving system according to Embodiment (3), FFT processing and phase detection can be used for noise detection, and are particularly effective means in a frequency modulation system. That is, the phase detection unit 37 functions as a demodulator, and a noise component can be extracted by passing the output of the phase detection unit 37 through the BPF 38 of the specific band. Therefore, by combining the FFT processing data of the FFT processing unit 31 and the phase detection signals processed by the phase detection unit 37 and the BPF 38, the noise can be accurately determined, and the noise detection accuracy and noise can be determined. Can be improved in accuracy.
[0131]
In the above embodiment (3), the output side of the front end unit 21 branches so that the FFT processing unit 31 and the phase detection unit 37 are connected. However, in another embodiment, Instead of the phase detection unit 37, it is also possible to adopt a configuration in which the output of the phase detection unit normally provided in the demodulation circuit unit 24 is branched and the phase detection signal can be taken into the noise discrimination unit 33A via the BPF 38. With such a configuration, it is not necessary to newly provide the phase detection unit 37, and it is possible to obtain substantially the same effect as the receiving system 10B while preventing an increase in the cost of the system.
[0132]
FIG. 9 is a block diagram schematically showing a main part of a receiving system according to Embodiment (4). However, the configuration of the receiving system according to the embodiment (4) is substantially the same as that of the receiving system 10 shown in FIG. 1 except for the filter unit 39 which is a noise detection unit. A different reference numeral is assigned to the noise determination unit 33B, and other components having the same function are assigned the same reference numerals, and description thereof is omitted.
[0133]
The receiving system according to the embodiment (4) is different from the receiving system according to the embodiment (1) in that the receiving system according to the embodiment (4) is configured by a plurality of filters having a specific limited band as an alternative to the FFT processing unit 31. In that a filter section 39 is provided.
[0134]
In the receiving system 10C shown in FIG. 9, the filters 1 to 4 forming the filter unit 39 are branched from the main signal line 20 on the output side of the front end unit 21 and connected in parallel. It is connected to the unit 33B.
[0135]
As a method of setting the limited band of each filter constituting the filter unit 39, for example, the limited band of the filter 1 is set to a bandwidth adjacent to 200 kHz around the IF intermediate frequency for detecting interference noise of FM broadcasting. The limited band of the filter 2 is set to a bandwidth higher than the filter 1 for pulse noise detection, and the limited band of the filter 3 is set to a lower band than the filter 1 for pulse noise detection. I do. The limited band of the filter 4 is set to the band of the IF intermediate frequency for detecting multipath noise.
[0136]
As described above, when the frequency characteristics of the noise to be removed are known in advance, the pass signal of each filter is set by setting the limited band in accordance with the frequency characteristic of the noise to be removed from each filter constituting the filter unit 39. By performing the processing, noise can be detected.
[0137]
Next, the noise discrimination / removal processing operation in the receiving system according to the embodiment (4) will be described based on the flowchart shown in FIG.
First, in step S31, the pass signal of the filter unit 39 is captured by the noise determination unit 33B, and the process proceeds to step S32.
[0138]
In step S32, the type of noise is determined on the basis of the passed signals of the filters 1 to 4 constituting the filter unit 39. In this case, interference noise can be determined from the signal passed through the filter 1, and pulse noise can be determined from the signals passed through the filters 2 and 3. Then, multipath noise can be determined from the passing signal of the filter 4, and after performing the noise determination processing of the passing signal of each filter, the process proceeds to step S33.
[0139]
In step S33, as a result of the noise determination process, it is determined whether any noise is detected. If it is determined that any noise is detected, the process proceeds to step S34, while no noise is detected. If it is determined that the process has been completed, the process ends.
[0140]
In step S34, a process of outputting a noise determination signal of the detected noise to the control signal output unit 34 based on the noise determination result is performed, and then the process proceeds to step S35.
[0141]
In step S35, the control signal output unit 34 outputs a control signal for performing the noise removing operation to the noise removing unit corresponding to each noise based on the noise determination signal, and ends the processing. As the control signal, a control signal similar to that described in the above embodiment (1) may be output according to each noise.
[0142]
According to the receiving system of the above embodiment (4), the restriction bands of the filters 1 to 4 constituting the filter unit 39 are individually set in advance in accordance with the frequency characteristics of the noise to be removed. It is possible to accurately detect noise having a frequency characteristic in a band. Therefore, it is possible to easily determine the type of noise from the signals passed through the filters 1 to 4.
[0143]
FIG. 11 is a block diagram schematically showing a main part of a receiving system according to Embodiment (5). However, the configuration of the receiving system 10D according to the embodiment (5) is substantially the same as the receiving system 10C according to the embodiment (4) except that the electric field strength monitoring unit 40 is provided. Then, different reference numerals are given to the electric field strength monitoring unit 40 and the noise determination unit 33C having different functions, and other components having the same functions are denoted by the same reference numerals, and the description thereof will be omitted. It is assumed that the receiving system 10D is employed in an FM broadcast receiving system.
[0144]
The electric field intensity monitoring unit 40 for monitoring the electric field intensity of the received radio wave is branched and connected to the output side of the filter 4 constituting the filter unit 39, and the output side of the electric field intensity monitoring unit 40 is connected to the noise determination unit 33C. ing.
[0145]
The filter 4 has a limited band set so that the level of the IF intermediate frequency (10.7 MHz in the case of FM broadcasting) can be monitored for multipath noise detection. , The electric field strength of the received radio wave can be detected. Then, when the electric field intensity falls below a predetermined electric field intensity, an electric field intensity reduction signal is output to the noise discriminating unit 33C. It should be noted that the time constant at which the level decreases greatly differs between the level decrease due to the occurrence of the multipath noise and the level decrease of the received electric field strength, so that the distinction is sufficiently possible.
[0146]
When the noise discrimination unit 33C detects the electric field strength reduction signal from the electric field strength monitoring unit 40, the noise discrimination processing is interrupted, and processing for canceling the noise removal operation is performed until the electric field strength reduction signal is no longer detected. It has become.
[0147]
Next, the operation of the noise determination / removal processing of the receiving system according to the embodiment (5) will be described based on the flowchart shown in FIG. However, this noise discrimination / removal processing operation has a configuration in which steps S41 and S42 are inserted between steps S31 and S32 in FIG. 10, and only the differences will be described here.
[0148]
First, in step S31, the pass signal of the filter unit 39 is captured by the noise determination unit 33C, and the process proceeds to step S41.
[0149]
In step S41, it is determined whether or not the electric field intensity reduction signal from the electric field intensity monitoring unit 40 has been detected. If it is determined that the electric field intensity reduction signal has not been detected, the process proceeds to step S32 and subsequent steps.
[0150]
On the other hand, if it is determined in step S41 that the electric field strength reduction signal has been detected, the process proceeds to step S42. In step S42, a process of interrupting the noise determination is performed, and the output of the control signal in the control signal output unit 34 is interrupted. After canceling the noise removal operation, the process ends.
[0151]
When the electric field strength of the received radio wave is reduced, it is difficult to distinguish between the signal and the noise due to the white noise, the detection accuracy of the noise is reduced, and the possibility of erroneous noise determination is increased. Therefore, according to the receiving system according to the embodiment (5), when the electric field strength falls below the predetermined level, the noise determination is interrupted so that the noise removing operation is not performed. A malfunction of the noise removing operation can be prevented.
[0152]
In the above embodiment (5), the case where the filter unit 39 is used as the noise detection unit has been described. However, the same processing can be performed even when the FFT processing unit 31 is provided instead of the filter unit 39. .
[0153]
In the above-described embodiment (5), when the level of the electric field intensity of the filter 4 monitored by the electric field intensity monitoring unit 40 falls below a predetermined level, an electric field intensity reduction signal is output to the noise discrimination unit 33C. Although the noise discrimination processing performed by the noise discrimination unit 33C is interrupted, in another embodiment, the noise discrimination unit 33C performs the noise discrimination processing according to the fluctuation level of the electric field strength monitored by the electric field strength monitoring unit 40. The noise detection sensitivity may be changed. With this configuration, for example, when the received electric field strength is reduced, the noise detection unit 33C performs control so as to weaken the noise detection sensitivity, thereby more finely controlling the erroneous operation of the noise removal operation. be able to.
[0154]
FIG. 13 is a block diagram schematically showing a main part of a receiving system according to Embodiment (6). However, the configuration of the receiving system 10E according to the embodiment (6) is substantially the same as that of the receiving system 10 shown in FIG. 1 except for the control signal output unit 34A and the intermediate frequency amplifier circuit unit 23A, so that different functions are provided. The control signal output unit 34a having the same symbol is assigned a different symbol, and other components having the same function are assigned the same symbol, and the description thereof is omitted here. It is assumed that the receiving system 10E is adopted as an AM broadcasting receiving system.
[0155]
The difference between the receiving system according to the embodiment (6) and the receiving system according to the embodiment (1) is that in the signal processing after the noise determination, it is determined that the pulse noise or the multipath noise is detected. Another point is that a zero complement control signal is output to the zero complement processing unit 23b of the intermediate frequency amplifier circuit unit 23A so as to complement zero the noise generation section of the IF signal.
[0156]
Next, a signal output processing operation in the receiving system according to Embodiment (6) will be described.
When the noise discrimination unit 33 determines that the IF signal contains pulse noise and / or multipath noise, the pulse noise discrimination signal and / or the multipath noise discrimination signal are output to the control signal output unit 34A. .
[0157]
The control signal output unit 34A causes the zero complement processing unit 23b of the intermediate frequency amplification circuit unit 23A to complement the IF signal in the noise generation section with zero based on the pulse noise determination signal and / or the multipath noise determination signal. Is performed to output the 0 complementation control signal.
The 0 complementation processing unit 23b that has received the 0 complementation control signal performs a 0 complementation process in a noise generation section to remove pulse noise and / or multipath noise included in the IF signal.
[0158]
When the noise discriminating unit 33 determines that the IF signal contains interference noise, an interference noise discrimination signal is output to the control signal output unit 34A. The control signal output unit 34A outputs a bandwidth change control signal for further narrowing the set bandwidth to the BPF 23a of the intermediate frequency amplifier circuit unit 23A based on the interference noise determination signal.
The band limiting unit that has received the bandwidth change control signal performs a process of changing the bandwidth to a narrow band so that interference noise is not included in the IF signal.
[0159]
According to the receiving system according to Embodiment (6), pulse noise and multipath noise in the IF signal can be removed by zero complementation in intermediate frequency amplifier circuit section 23A. The noise of the IF signal in the intermediate frequency amplifying circuit 23A has a smaller signal distortion than the noise of the demodulation output and the time spread of the noise is narrower. The time required for removal can be shortened, and it is particularly effective in an amplitude modulation application such as AM radio.
Further, by changing the bandwidth of the BPF 23a to a narrow band, for example, interference noise can be removed, and control signal output processing corresponding to the type of noise can be performed.
[0160]
In the above-described embodiment (6), the case has been described where the 0 complementation processing unit 23b is included in the intermediate frequency amplification circuit unit 23A, but the 0 complementation processing unit 23b is provided in a stage preceding the demodulation circuit unit 24. If so, a similar effect can be obtained.
[0161]
In the above embodiment (6), when it is determined that pulse noise or multipath noise is included, the control signal output unit 34A outputs the 0 complement control signal to the 0 of the intermediate frequency amplification circuit unit 23A. Although configured to output to the complementing processing unit 23b, in another embodiment, the intermediate frequency amplifying circuit unit 23A includes a pre-complementing processing unit that performs a process of complementing a noise generation section with a signal immediately before noise generation. The control signal output unit 34A is arranged to output to the pre-completion processing unit a pre-completion control signal for performing pre-completion processing with an output immediately before noise generation, or A linear interpolation processing unit for complementing the noise generation section with a signal connecting the front and rear of the section with a straight line is provided in the amplification circuit unit 23A, and the control signal output unit 34A is configured to It can also be adapted to output a linear interpolation control signal to the line interpolation processing.
[0162]
Alternatively, based on the IF signal storage means for storing the IF signal at the subsequent stage of the intermediate frequency amplification circuit section 23A, and the IF signal stored in the IF signal storage means, a normal IF signal in a noise generation section is predicted and created. If the receiving system further includes a predicted output creating unit that performs the prediction output switching unit that switches the noise occurrence section to the predicted output instead of the IF signal, the control signal output unit 34A A predictive output switching control signal is output to the predictive output switching means based on a pulse noise determination signal or a multipath noise determination signal sent from the Switching to an output can also remove noise. Note that the prediction output creating means can be constituted by an adaptive filter.
[0163]
FIG. 14 is a block diagram schematically showing a main part of a receiving system according to Embodiment (7). However, the configuration of the receiving system 10F according to the embodiment (7) is substantially the same as the receiving system 10 shown in FIG. 1 except for the noise removal processing filter 25, the memory 26, and the control signal output unit 34B. Here, different reference numerals are assigned to the noise removal filter 25, the memory 26, and the control signal output unit 34B having different functions, and other components having the same functions are assigned the same reference numerals, and description thereof is omitted. And
[0164]
The noise removal processing filter 25 is provided between the intermediate frequency amplification circuit section 23 and the demodulation circuit section 24, and is connected to a memory 26 in which filter coefficients corresponding to the characteristics and types of noise are stored.
[0165]
The output side of the control signal output section 34B is connected to the noise removal processing filter 25. The noise removal processing filter 25 takes in the filter coefficient change control signal output from the control signal output section 34B and changes the filter coefficient. A suitable filter coefficient is read from the memory 26 based on the control signal, and a filter coefficient suitable for the determined noise can be set.
[0166]
The noise removal processing filter 25 is configured by a digital signal processor or the like. The filter configuration of the noise removal processing filter 25 may be a single configuration or a plurality of configurations, and the filter configuration may be changed according to noise.
[0167]
Next, the noise removal processing operation in the receiving system according to the embodiment (6) will be described based on the flowchart shown in FIG. Note that the noise determination processing is the same as the processing operation described in the above-described embodiment (1), and thus description thereof is omitted here.
[0168]
First, in step S51, the control signal output unit 34B determines whether or not the noise determination signal from the noise determination unit 33 has been detected. If it is determined that the noise determination signal has not been detected, the process ends. On the other hand, if it is determined that the noise determination signal has been detected, the process proceeds to step S52.
[0169]
In step S52, a filter coefficient change control signal for changing to a filter coefficient suitable for removing the determined noise is output to the noise removal processing filter 25 based on the detected noise determination signal, and the process proceeds to step S53.
[0170]
In step S53, the noise removal processing filter 25 performs a process of reading out the most appropriate filter coefficient for noise removal determined from the filter coefficients stored in the memory 26 based on the filter coefficient change control signal. Proceed to S54.
[0171]
In step S54, the read filter coefficient setting process is performed, and the process ends. The noise removal filter 25 removes all noise included in the IF signal selected and amplified by the intermediate frequency amplification circuit 23.
[0172]
According to the receiving system of the embodiment (7), by removing the filter coefficient of the noise removal processing filter 25 according to the characteristics and type of the determined noise, it is possible to accurately remove and suppress various noises. It can be carried out. Therefore, the hardware configuration of the receiving system 10F can be simplified, and the filter coefficient can be changed, so that it is possible to flexibly deal with detected noise. Further, since the filter coefficients are stored in the memory 26, it is not necessary to obtain the filter coefficients by arithmetic processing, and the processing can be reduced.
[0173]
In the above embodiment (7), the memory 26 in which the filter coefficients corresponding to the respective noises are stored in advance, and the appropriate filter coefficients are read out from the memory in accordance with the characteristics and types of the determined noises. Although the filter coefficient of the noise removal processing filter 25 is changed, in another embodiment, the filter coefficient may be changed to a filter coefficient obtained by calculation without storing the filter coefficient in the memory 26.
[0174]
Further, as another embodiment, if the filter coefficients stored in the memory 26 cannot be optimized, an appropriate filter coefficient according to the situation is calculated, and the filter coefficient is switched to the calculated filter coefficient. In addition to appropriate removal or suppression of noise, the calculated filter coefficients and the determined noise information may be stored in the memory 26. With this configuration, it is possible to cope with even more noise characteristics and types, and the noise removing function can be further enhanced.
[0175]
FIG. 16 is a block diagram schematically showing a main part of a receiving system according to Embodiment (8). However, the configuration of the receiving system 10G according to Embodiment (8) is substantially the same as that of the receiving system 10 shown in FIG. 1 except for the diversity antenna unit 27 and the control signal output unit 34C. Diversity antenna section 27 and control signal output section 34C having different functions are denoted by different reference numerals, and other components having the same function are denoted by the same reference numerals, and description thereof will be omitted.
[0176]
The diversity antenna unit 27 includes a first antenna 27a, a second antenna 27b, and an antenna changeover switch 27c, and the first antenna 27a and the second antenna 27a And a larger output signal is selected from the plurality of antenna outputs.
[0177]
The control signal output unit 34C receives the multipath noise discrimination signal output from the noise discrimination unit 33, and outputs an antenna selection control signal to the diversity antenna unit 27 for selecting an adopted antenna. I can do it.
[0178]
The diversity antenna unit 27 receives the antenna selection control signal and performs an antenna switching process so that a large output signal is selected from the antenna outputs of the first antenna 27a or the second antenna 27b. It has become.
[0179]
When receiving the pulse noise determination signal from the noise determination unit 33, the control signal output unit 34C outputs a zero complement control signal to the zero complement processing unit 24a of the demodulation circuit unit 24, When the determination signal is received, a process of outputting a bandwidth change control signal to the BPH 23a of the intermediate frequency amplification circuit unit 23 is also performed.
[0180]
According to the receiving system of the embodiment (8), the control signal output unit 34C outputs the antenna selection control signal for selecting the adopted antenna to the diversity antenna unit 27, so that the diversity signal is output. The city antenna unit 27 can select an adopted antenna based on an antenna selection control signal. When multipath noise is detected, the city antenna unit 27 can appropriately select an adopted antenna, and allows the receiving system 10G to receive a multi-pass noise. Intrusion of path noise can be prevented.
[Brief description of the drawings]
FIG. 1 is a block diagram schematically showing a main part of a receiving system according to Embodiment (1) of the present invention.
FIGS. 2A and 2B are diagrams for explaining pulse noise detection processing in the receiving system according to the embodiment (1), where FIG. 2A shows a signal waveform of an IF signal including pulse noise, and FIG. An output signal waveform, and (c) shows FFT processing data of an IF signal containing pulse noise and an IF signal containing no pulse noise.
FIGS. 3A and 3B are diagrams for explaining multipath noise detection processing in the receiving system according to the embodiment (1), where FIG. 3A shows a signal waveform of an IF signal including multipath noise, and FIG. The signal waveform of the demodulated output at this time, (c) shows FFT processing data of an IF signal containing multipath noise and an IF signal containing no multipath noise.
FIG. 4 shows FFT processing data of an IF signal including interference noise in the receiving system according to the embodiment (1).
FIG. 5 is a flowchart showing a noise discrimination / removal processing operation in the receiving system according to the embodiment (1).
FIG. 6 is a block diagram schematically showing a main part of a receiving system according to Embodiment (2).
FIG. 7 is a block diagram schematically showing a main part of a receiving system according to Embodiment (3).
FIG. 8 is a flowchart showing a noise discrimination / removal processing operation in the receiving system according to the embodiment (3).
FIG. 9 is a block diagram schematically showing a main part of a receiving system according to Embodiment (4).
FIG. 10 is a flowchart showing a noise discrimination / removal processing operation in the receiving system according to the embodiment (4).
FIG. 11 is a block diagram schematically showing a main part of a receiving system according to Embodiment (5).
FIG. 12 is a flowchart showing a noise discrimination / removal processing operation in the receiving system according to the embodiment (5).
FIG. 13 is a block diagram schematically showing a main part of a receiving system according to Embodiment (6).
FIG. 14 is a block diagram schematically showing a main part of a receiving system according to Embodiment (7).
FIG. 15 is a flowchart showing a noise removal processing operation in the receiving system according to the embodiment (7).
FIG. 16 is a block diagram schematically showing a main part of a receiving system according to Embodiment (7).
FIG. 17 is a block diagram schematically showing a main part of a conventional receiving system.
[Explanation of symbols]
10, 10A to 10G receiving system
20 Main signal line
21 Front end
22 Delay part
23 Intermediate frequency amplifier
24 Demodulation circuit
25 Noise removal processing filter section
26 memory
27 Diversity antenna section
31 FFT processing unit
32 signal processing means
33, 33A, 33B, 33C Noise discriminator
34, 34A, 34B, 34C control signal output unit
35 memory
36, 38 BPF
37 Phase detector
39 Filter section
40 Electric field strength monitoring unit

Claims (28)

In a receiving system configured to include a frequency conversion unit that converts an input signal into an intermediate frequency signal (hereinafter, referred to as an IF signal), an intermediate frequency processing unit, and a demodulation unit in a main signal line,
Noise detection means for processing the IF signal to detect noise;
A signal processing unit for performing signal processing for removing noise in accordance with characteristics of each noise detected by the noise detection unit. The signal processing means,
Noise determination means for determining the type of noise based on the detection result by the noise detection means,
2. A control signal output means for outputting a control signal for performing noise removal in accordance with the type of noise determined by said noise determination means to a predetermined noise removal means. Receiving system. The noise detection means,
3. The receiving system according to claim 2, wherein a high-speed Fourier transform process (hereinafter, referred to as an FFT process) of the IF signal is used. The receiving system according to any one of claims 1 to 3, wherein a band limiting unit is provided before the noise detecting unit. 5. The receiving system according to claim 4, wherein said band limiting means is also used as one included in said main signal line. The noise detection means,
3. The receiving system according to claim 1, further comprising a plurality of filter units having a specific limited band connected in parallel. The noise determination means,
First monitoring means for monitoring the level of each frequency component of the IF signal subjected to the FFT processing;
Level storage means for storing a level of a specific frequency component of the IF signal monitored by the first monitoring means;
Second monitoring means for monitoring a change in a temporal level of a specific frequency component of the IF signal stored in the level storage means,
4. The receiving system according to claim 3, wherein a type of noise is determined based on monitoring results of said first monitoring means and said second monitoring means. The noise detecting means further includes a phase detecting means for detecting a phase of the IF signal,
8. The receiving system according to claim 3, wherein said noise discriminating means discriminates a type of noise based on phase detection data detected by said phase detecting means. 9. The receiving system according to claim 8, wherein said phase detecting means is also used as one included in said demodulating means. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
An output of a zero complement control signal for zero complementing a noise generation portion of the demodulated output from the demodulator, and / or a bandwidth change control for changing the bandwidth of the band limiter to the band limiter. The receiving system according to any one of claims 2 to 9, wherein a signal is output according to a type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
An output of a pre-completion control signal for pre-complementing a noise generation portion of the demodulation output from the demodulation means, and / or a bandwidth for changing the bandwidth of the band restriction means with respect to the band restriction means 10. The receiving system according to claim 2, wherein the output of the change control signal is performed according to the type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
An output of a linear interpolation control signal for linearly interpolating the demodulation output from the demodulation means and / or an output of a bandwidth change control signal for changing the bandwidth of the band limiting means to the band limiting means. The reception system according to claim 2, wherein the reception is performed according to a type of noise. Bandwidth limiting means for varying the bandwidth,
Demodulation output storage means for storing a demodulation output from the demodulation means,
Prediction output creation means for predicting and creating a normal demodulation output in a noise generation section based on the demodulation output stored in the demodulation output storage means;
Predictive output switching means for switching a noise occurrence section to a predictive output instead of the demodulated output,
The control signal output means,
The output of the predicted output switching control signal to the predicted output switching means and / or the output of the bandwidth change control signal for changing the bandwidth of the band limiting means to the band limiting means are classified into types of noise. The receiving system according to any one of claims 2 to 9, wherein the receiving system is performed in accordance with: Bandwidth limiting means for varying the bandwidth of the main signal line,
An MPX circuit is provided downstream of the demodulation means,
The control signal output means,
An output of a stereo separation control signal for causing the MPX circuit to change the stereo separation, and / or a change of a bandwidth change control signal for changing the bandwidth of the band limiting unit to the band limiting unit. The receiving system according to any one of claims 2 to 9, wherein output is performed according to a type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
Outputting a mute control signal for muting the demodulated output from the demodulation means and / or outputting a bandwidth change control signal for changing the bandwidth of the band limiting means to the band limiting means. The receiving system according to any one of claims 2 to 9, wherein output is performed according to a type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
An output of a frequency characteristic control signal for attenuating a high band in the demodulation output from the demodulation means, and / or a change of a bandwidth change control signal for changing the bandwidth of the band limitation means to the band limitation means. The receiving system according to any one of claims 2 to 9, wherein output is performed according to a type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
An output of a zero complement control signal for causing the intermediate frequency processing unit to perform zero complementation of a noise generation point of an IF signal, and / or a band for changing a bandwidth of the band limiting unit with respect to the band limiting unit. The receiving system according to any one of claims 2 to 9, wherein the output of the width change control signal is performed according to the type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
Output of a pre-supplementation control signal for pre-complementing the noise generation point of the IF signal to the intermediate frequency processing means and / or changing the bandwidth of the band-limiting means to the band-limiting means The receiving system according to any one of claims 2 to 9, wherein the output of the bandwidth change control signal is performed according to the type of noise. The main signal line includes a band-limiting unit capable of changing a bandwidth,
The control signal output means,
An output of a linear interpolation control signal for linearly interpolating a noise generation point of an IF signal to the intermediate frequency processing unit, and / or a band for changing a bandwidth of the band limiting unit to the band limiting unit. 10. The receiving system according to claim 2, wherein the output of the width change control signal is performed according to the type of noise. Bandwidth limiting means for varying the bandwidth,
IF signal storage means for storing an IF signal from the intermediate frequency processing means,
Prediction output creating means for predicting and creating a normal IF signal in a noise occurrence section based on the IF signal stored in the IF signal storage means;
Prediction output switching means for switching a noise generation section to a prediction output instead of the IF signal,
The control signal output means,
The output of the predicted output switching control signal to the predicted output switching means and / or the output of the bandwidth change control signal for changing the bandwidth of the band limiting means to the band limiting means are set to the type of noise. The receiving system according to any one of claims 2 to 9, wherein the receiving system is performed in response to the request. 21. A combination of three or more types of processing performed by the control signal output unit according to any one of claims 10 to 20 according to the characteristics and types of noise determined by the noise determination unit. A receiving system. Equipped with electric field intensity monitoring means for monitoring the electric field intensity of the received radio wave,
The noise determination means,
The apparatus according to any one of claims 1 to 9, further comprising a noise determination interrupting unit that interrupts noise determination when the electric field intensity monitored by the electric field intensity monitoring unit is equal to or lower than a predetermined level. Receiving system. Equipped with electric field intensity monitoring means for monitoring the electric field intensity of the received radio wave,
The noise determination means,
The reception according to any one of claims 1 to 9, further comprising a noise detection sensitivity changing unit that changes a noise detection sensitivity according to an electric field intensity monitored by the electric field intensity monitoring unit. system. The main signal line includes a filter unit as the noise removing unit,
The control signal output means,
10. A filter coefficient change control signal is output to the filter means so as to change the filter coefficient to an appropriate filter coefficient according to the characteristics and type of the determined noise. The receiving system according to any one of the above items. A filter coefficient storage unit in which filter coefficients according to characteristics and types of noise are stored;
The filter means,
A method for reading out an appropriate filter coefficient from the filter coefficients stored in the filter coefficient storage means based on the filter coefficient change control signal, and performing noise removal by switching to the filter coefficient. Item 25. The receiving system according to Item 24. A filter coefficient calculating means for calculating an optimum filter coefficient by calculation when the filter coefficient stored in the filter coefficient storing means cannot cope with the filter coefficient;
26. The reception system according to claim 25, further comprising: a filter coefficient update storage unit that updates and stores the filter coefficient obtained by the filter coefficient calculation unit in the filter coefficient storage unit. The main signal line includes a filter unit as the noise removing unit,
The filter means includes a plurality of filter means,
The control signal output means,
The filter means outputs a filter configuration change control signal for changing the filter means to an appropriate filter configuration in accordance with the characteristics and type of the determined noise. The receiving system according to claim 2. Diversity means for selecting a large output signal from a plurality of antenna outputs in the main signal line,
The control signal output means,
The receiving system according to any one of claims 2 to 9, wherein the diversity system outputs an antenna selection control signal for selecting an adopted antenna.

Images