JPH06244745A - Noise suppression circuit - Google Patents

Abstract

PURPOSE:To satisfactorily reduce noise without deteriorating a receiving sensitivity. CONSTITUTION:Noise components are extracted from one distributed output of a distributing part 12 by a high pass filter 13. The noise components are invertible-amplified by an invertible amplifying part 14, and a signal whose polarity is opposed and whose absolute value is equal to the noise components is prepared. Then, the other output of the distributing part is delayed by a delay part 15 only in the processing time of the high pass filter 13 and the invertible amplifying part 14. Thus, the position of the noise components of the other output of the distributing part 12 is matched with the position on a time axis of the noise components being the output of the invertible amplifying part 14. The signal whose polarity is inverted and whose absolute value is equal to the noise components is added to the noise components by an adding part 16, and the noise components are offset. When the signal whose polarity is inverted and whose absolute value is equal to the noise components is added to the noise components, and the noise components are offset, the distortion of the signal can be difficult to be generated, and the deterioration of the receiving sensitivity can not be generated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise suppressing circuit for reducing noise in an FM receiver.

[0002]

2. Description of the Related Art In an FM receiver, the signal suppression phenomenon occurs at the sensitivity limit, so that the carrier suppression effect is reduced.
The noise level will increase. This appears as a noise component called triangle noise in the demodulation output. This noise component has a larger energy density than the signal component.
Since the noise component is impulse-like, a filter or the like exhibits an impulse response, the time response becomes longer than the time width of the input noise, and the signal component cannot be discriminated by noise.

As a noise reduction method at such a sensitivity limit, conventionally, a method of reducing impulse noise such as automobile noise has been used. FIG. 4 shows a super-heterodyne FM receiver for data communication, which is basically an RF amplifier 1 for amplifying an antenna input.
And the output frequency of the RF amplifier 1 is set to the intermediate frequency (I
F) a frequency conversion unit 2 including a mixer and a local oscillator, and an IF filter 3 extracting an intermediate frequency signal.
And an IF amplifier 4 that amplifies the output of the IF filter 3,
The demodulator 5 demodulates the output of the IF amplifier 4, the smoother 6 that smoothes the demodulated output, and the waveform shaper 7 that shapes the output of the smoother 6.

In this FM receiver, the signal received by the antenna is amplified by the RF amplifier 1, the amplified output is dropped to an IF frequency by the frequency conversion unit 2, and the IF frequency component is IF.
It is extracted by the filter and amplified by the IF amplifier 4. The amplified output is demodulated by the demodulation unit 5, and the output smoothed by the smoothing unit 6 is waveform-shaped by the waveform shaping unit 7 to be restored to a data signal. In the FM receiver of FIG. 4, as a configuration for reducing noise, a high-pass filter (HPF) 8 that extracts a high-frequency component generated in the output of the frequency conversion unit 2 and a noise component is extracted.
A noise amplification section 9 for amplifying the output of the high-pass filter 8 and a noise detection section 1 for detecting the amplified noise component.
0, and a control unit 11 that adjusts the gain of the IF amplifier 4 according to the detected noise output.

In the FM receiver, the noise component is extracted from the output of the frequency conversion unit 2 using the high-pass filter 8, the extracted noise component is amplified by the noise amplification unit 9, and detected by the noise detection unit 10. From the detected output, the control unit 11 determines whether or not it is a noise component having a peak value equal to or higher than the problem level. Then, the gain of the IF amplifier 4 is reduced during the period in which the noise component causing the problem exists, so that the IF amplifier 2 is prevented from outputting a large signal component due to the noise component.

According to this noise reduction method, since the noise component is detected from the output of the frequency conversion unit 2, there are advantages that the response is good and the impulse noise component can be detected. In the above case, the output of the IF amplifier 4 is prevented from being output according to the noise component by limiting the gain of the IF amplifier 4 to a small value. In some cases, a variable one is used, and when a problem noise component exists, the pass band of the IF filter 3 is narrowed so that an output corresponding to the noise component is not input to the IF amplifier 4. Also, there is a configuration in which the high-pass filter 8 is not used.

[0007]

By the way, according to the above noise reduction method, the signal component is suppressed to be small during the period when noise is present, that is, the signal component is suppressed during the period when noise is substantially present. It is designed to be cut. If the signal is cut in this way, the waveform shaping section 7 cannot restore a correct signal. Therefore, in the FM receiver, the smoothing section 6 is provided so that the cut portion is flattened so that the correct signal can be restored by the waveform shaping section 7.

However, depending on the time width of the noise component, the signal portion cut by the smoothing unit 6 cannot be completely restored, and the signal component is cut to the output of the smoothing unit 6 as shown at the right end of FIG. 5 (a). It causes scratches. Here, when the waveform shaping section 7 shapes the waveform of the signal by comparing it with the reference level V _TH , as shown in FIG. 5B, there is a problem that an unnecessary signal D is generated due to the scratch. there were. Also,
In some cases, a waveform similar to the signal distortion may be newly generated due to the vibration phenomenon of the smoothing unit 6.

Such a phenomenon becomes more prominent as the receiving sensitivity reaches the limit level. FIG. 6A shows an output waveform of the demodulation unit 5 when the reception sensitivity is at the limit level. The carrier suppression effect does not work effectively, but rather the signal is suppressed by the noise component, so that the noise component is detected. The time width of the output is increased, the output of the demodulation unit 5 is mostly smoothed by the smoothing unit 6, and the output of the waveform shaping unit 7 becomes the output waveform shown in FIG. 6B. In this case, the data "1", "
There is a problem in that when the receiving sensitivity is poor and the receiving sensitivity is poor, the receiving sensitivity is rather lowered.

Further, although the response of the noise component is good, a large amount of time delay occurs in the subsequent processing, so that it is not possible to sufficiently follow the fluctuation of the intermediate frequency in which the luminous flux responds, and the noise is surely generated. In some cases, it cannot be removed. Further, in this type of FM receiver, a quadrature detection method is adopted as the demodulation section 5 to increase the reception sensitivity, but the above noise reduction method results in impairing the high sensitivity reception performance. There was a problem of becoming.

The present invention has been made in view of the above points, and an object of the present invention is to provide a noise suppressing circuit capable of satisfactorily reducing noise without lowering reception sensitivity. It is in.

[0012]

According to the present invention, in order to achieve the above object, a distributor for distributing an output of a demodulator, a high-pass filter for passing a high-frequency component of one distribution output of the distributor, and a high-pass filter. An inverting amplification unit that inverts and amplifies the signal that has passed through the filter, a delay unit that delays and outputs the other distributed output of the distribution unit by the time required for signal processing in the high-pass filter and the inverting amplification unit, the delay unit and the inverting amplification unit. And an adder that adds outputs from the unit.

[0013]

The present invention has the above-mentioned configuration,
A noise component is extracted from one distribution output of the distribution unit by a high-pass filter, and the noise component is inverted and amplified by the inverting amplification unit,
A signal whose polarity is opposite to that of the noise component and whose absolute value is equal in magnitude is created. The delay unit delays the other output of the distribution unit by the processing time of the high-pass filter and the inverting amplification unit, and the other output of the distribution unit is placed at the position on the time axis of the noise component that is the output of the inverting amplification unit. Match the positions of the noise components. The addition unit cancels the noise component by adding the noise component and the signal whose polarity is opposite to that of the noise component and whose absolute value is equal in magnitude. In this way, when a signal whose polarity is opposite to that of the noise component and whose absolute value is equal in magnitude is added to the noise component to cancel them, signal distortion is less likely to occur and reception sensitivity is not reduced.

[0014]

1 to 3 show an embodiment of the present invention. The FM receiver of this embodiment includes the RF amplifier 1, the frequency conversion unit 2, the IF filter 3, the IF amplifier 4, the demodulation unit 5, and the waveform shaping unit 7 of FIG. 4, and replaces the smoothing unit 6 of FIG. A noise suppression circuit A is provided. The noise suppression circuit A distributes the output of the demodulator 5 to the distributor 12, the high-pass filter (HPF) 13 that allows the high-frequency component of one of the signals distributed by the distributor 12 to pass, and the output of the high-pass filter 13. An inverting amplification section 14 for inverting amplification and a delay section 15 for delaying the other signal distributed by the distribution section 12 for a predetermined time.
And an adder 16 for adding the output of the delay unit 15 and the output of the inverting amplifier 14.

For example, assuming that the demodulated output shown in (a) of FIG. 3 is obtained and the output is passed through the high-pass filter 11, the signal of (b) in FIG. 3 is obtained. Here, the time constant of the components forming the high-pass filter 11 is set to be small so that the triangular wave noise component is mainly extracted.
When this signal b is inverted and amplified by the inverting amplifier 14,
The waveform is as shown in (b).

With respect to the delay time of the delay unit 15, the other distribution output of the distribution unit 2 is controlled by the high-pass filter 13 and the inverting amplification unit 1.
The output of the inverting amplifier 14 is input to the adder 16 and at the same time the other signal of the distributor 12 is added to the adder 1
6 is input. As a result, the output timing of the signal that is the output of the inverting amplification section 14 with the polarity of the noise component inverted, and the output timing of the noise component included in the output of the delay section 15 coincide with each other.

Further, the gain of the output of the inverting amplification section 14 is adjusted so that the noise component output from the delay section 15 has the same absolute value level. Specifically, the amplification factor of the inverting amplification unit 14 is set so as to amplify the amount of attenuation by the high pass filter 13. Therefore, if the output of the delay unit 15 and the output of the inverting amplification unit 14 are added in the addition unit 16, the high frequency component included in the demodulation output,
That is, the noise components are canceled out. The output of the adder 12 has the waveform shown in FIG. In this way, if a signal whose polarity is opposite to that of the noise component and whose magnitude is the same in absolute value is added to the noise component to cancel it, it is possible to prevent the noise component from being cut as in the case of cutting the noise component from the signal. That is, the noise component can be removed without causing signal distortion. In particular, it is effective only to remove the triangular wave noise component at the sensitivity limit, and the signal is not damaged as in the conventional method, so that the reception sensitivity is not deteriorated. Further, when there is no input signal, the noise suppression circuit A operates as if a so-called squelch function is activated because the noise components are completely canceled and removed.

FIG. 2 shows a specific configuration of FIG. Distributor 1
2 is composed of diodes D ₁ and D ₂ , and the high-pass filter 13 is composed of a capacitor C ₁ , a coil L ₁ and a resistor R ₁ , and the time constant is set small. Further, the inverting amplification section 15 is composed of an operational amplifier OP ₁ , and has resistors R ₂ and R ₂ .
_{In 3} , the amplification factor (R ₂ / R ₃ ) is adjusted. Adder 16
Uses an operational amplifier OP ₂ .

[0019]

As described above, the present invention distributes the output of the demodulator, the high-pass filter that allows the high-frequency component of one of the distributed outputs of the distributor to pass, and the signal that has passed through the high-pass filter is inverted and amplified. An inverting amplification unit, a delay unit that delays the other distributed output of the distribution unit by the time required for signal processing in the high-pass filter and the inverting amplification unit, and adds the outputs of the delay unit and the inverting amplification unit. Since the noise component is provided, it is possible to cancel the noise component by adding a signal whose polarity is opposite to that of the noise component and whose absolute value is equal in magnitude to the noise component. Moreover, since a signal whose polarity is opposite to that of the noise component and whose absolute value is equal in magnitude is added to the noise component to cancel it, signal distortion is less likely to occur,
No reduction in reception sensitivity occurs.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a main part of an embodiment of the present invention.

FIG. 2 is a specific circuit diagram of the above.

FIG. 3 is an operation explanatory diagram of the above.

FIG. 4 is a block diagram showing a circuit configuration of a conventional FM receiver.

FIG. 5 is an explanatory diagram of a problematic phenomenon of the above.

FIG. 6 is an explanatory diagram of another phenomenon causing the same problem as above.

[Explanation of symbols]

 A noise suppression circuit 5 demodulation unit 12 distribution unit 13 high-pass filter 14 inverting amplification unit 15 delay unit 16 addition unit

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[Procedure amendment]

[Submission date] July 5, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0002

[Correction method] Change

[Correction content]

[0002]

2. Description of the Related Art In an FM receiver, since the signal component decreases at the sensitivity limit, the carrier suppression effect decreases,
The noise level will increase. This appears as a noise component called triangle noise in the demodulation output. This noise component has a larger energy density than the signal component.
Since the noise component is impulse-like, a filter or the like exhibits an impulse response, the time response becomes longer than the time width of the input noise, and the signal component cannot be discriminated by noise.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction content]

However, by the time width of the noise component can not completely repair the cut signal portion by the smoothing section 6, cutting the signal component in the output of the smoothing section 6 as shown in the right end of FIGS. 5 (a) It causes scratches. Here, when the waveform shaping section 7 shapes the waveform of the signal by comparing it with the reference level V _TH , as shown in FIG. 5B, there is a problem that an unnecessary signal D is generated due to the scratch. there were. In some cases, the vibration phenomenon of the smoothing unit 6 may cause a new waveform similar to the signal distortion.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0010

[Correction method] Change

[Correction content]

Further, although the response of the noise component is good, since a large amount of time delay is generated in the subsequent processing, it is not possible to sufficiently follow the fluctuation of the intermediate frequency which responds at high speed , and the noise is surely detected. In some cases, it cannot be removed. Further, in this type of FM receiver, a quadrature detection method is adopted as the demodulation section 5 to increase the reception sensitivity, but the above noise reduction method results in impairing the high sensitivity reception performance. There was a problem of becoming.

Claims (1)

[Claims] 1. A noise suppression circuit for reducing noise in an FM receiver, comprising a distributor that distributes the output of a demodulator, a high-pass filter that allows the high-frequency component of one of the distributed outputs of the distributor to pass, and a high-pass filter. An inverting amplification section for inverting and amplifying the signal passed through, a delay section for delaying the other distributed output of the distribution section by the time required for signal processing in the high-pass filter and the inverting amplification section, and a delay section and an inverting amplification section. And a summing unit for summing the outputs of the noise suppression circuit and the noise suppression circuit.