JP2821374B2 - Receiver - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiving device.

[0002]

2. Description of the Related Art FIG. 14 is a block diagram showing the configuration of an example of a conventional receiving apparatus. As shown in FIG. 14, this conventional example is a receiving device to which an AGC system is applied, and a high-frequency amplifier circuit 2, a tuning circuit 3 , A level detection circuit 5, an intermediate frequency conversion circuit 8, a BPF (bandpass filter) 10, and an intermediate frequency amplification / detection circuit 13. In FIG. 14, a reception signal input from an antenna input terminal 1 is input to a high frequency amplifier circuit 2 and amplified, and an output signal thereof is selected and output by a tuning circuit 3 to a desired reception frequency signal 4, and an intermediate frequency signal is output. It is input to the conversion circuit 8. The reception frequency signal 4 is
At the same time, the signal is input to a level detection circuit 5 forming an AGC circuit, and its output level is detected. A gain control signal 6 corresponding to the detected level is output and input to the high frequency amplifier circuit 2. In the high frequency amplifier circuit 2, the gain for the received signal is controlled by the gain control signal 6, so that the level of the received frequency signal 4 output from the tuning circuit 3 is kept constant. On the other hand, the intermediate frequency conversion circuit 8
In, the frequency of the reception frequency signal 4 is converted to a predetermined intermediate frequency, an intermediate frequency signal is output, and the intermediate frequency signal is input to the BPF 10 having the intermediate frequency as the center frequency, and the output is output to the intermediate frequency amplification / detection circuit 13. The input signal is amplified and detected, and an audio signal is output via the audio signal output terminal 14.

As described above, the signal level of the reception frequency signal 4 output from the tuning circuit 3 and input to the intermediate frequency conversion circuit 8 is kept constant by the feedback control action of the level detection circuit 5 forming the AGC circuit. But, for example,
In an AM broadcast or the like, the reception level of a reception signal at the antenna input terminal 1 generally fluctuates at any time.
The AGC circuit is an indispensable component for the AM receiving apparatus in order to obtain a stable reception level by the AM receiving apparatus that wants to receive the M broadcast. This means
The same applies to the FM receiver. In this case, the reception band characteristic of the receiving apparatus having the conventional AGC circuit is defined by the frequency characteristics of the tuning circuit 3 and the BPF 10. Generally, the band characteristic of the tuning circuit 3 is as shown in FIG.
As shown in FIG.
kHz, and the bandwidth is wider than the band characteristic of the BPF 10 (about ± 50 kHz with respect to the center frequency).
Thus, the reception band characteristics of the receiving device are determined by the band characteristics of the BPF 10. However, in general,
As shown in FIG. 15, the band characteristic of the ceramic filter used for the BPF 10 is ± 100 kHz.
In the vicinity of the detuning point, there is a passing region where the level is reduced by about -50 dB.
If there is a broadcast station at the point detuned by z, BP
There is a problem in that voice, noise, and the like that cannot be removed by F10 are output from the voice output terminal 14 as interference signals.

FIG. 17A shows the level of an interference signal detuned by 100 kHz at the audio output terminal 14 and the output characteristics of the audio output signal. In FIG. 17, the horizontal axis is 100 k
The vertical axis shows the desired audio signal output level and the output level of the interference signal (voice, noise) at the audio output terminal 14.

On the other hand, in an AGC circuit in a conventional receiving apparatus, a signal level of a received frequency signal 4 to an intermediate frequency converting circuit 8 is detected by a level detecting circuit 5, and a gain output from the level detecting circuit is obtained. Since the gain of the high-frequency amplifier circuit 2 is controlled by the control signal 6, the frequency characteristics of the received signal output from the high-frequency amplifier circuit 2 and input to the tuning circuit 3 with the signal level controlled are adjusted to the tuning circuit 3. Is defined by the band characteristic of That is, if the signal is within the band characteristics of the tuning circuit 3, even a signal other than the desired received signal is output via the tuning circuit 3. As can be seen from the band characteristic of the tuning circuit 3 shown in FIG.
The frequency is about 00 kHz to ± 300 kHz, and a further improvement in the accuracy with respect to the band limitation involves a problem that an increase in the configuration of the tuning circuit 3 and an increase in the number of adjustment steps are caused. For this reason, when there is another broadcasting station whose frequency is detuned by about 200 kHz to 300 kHz from the desired tuning frequency signal, the AGC operation in the receiving apparatus is performed in accordance with the desired reception frequency detuned. It operates in the same way as when receiving a frequency signal. As a result, the signal level of the desired reception signal is suppressed by the interference signal from another broadcast station, and as shown in FIG. 17B, the level of the interference sound, noise, etc., increases with the increase of the interference signal level. Increases and B
Although the PF 10 removes the signal to some extent, the audio output terminal 14 outputs an audio signal having a level such as noise.

[0006]

In the above-mentioned conventional receiving apparatus, the band characteristic of the BPF corresponding to the intermediate frequency signal is reduced by 10% due to the characteristic characteristic of the ceramic filter.
At the detuning point of about 0 kHz, a sub-pass frequency region is interposed, which causes an interfering signal from another station or the like which cannot be removed by the BPF, and outputs the interfering audio signal and noise together with the audio output signal. Being
There is a disadvantage that the audio output signal is significantly impaired.

In the conventional AGC circuit of the receiving apparatus, a signal level of a reception frequency signal output from a tuning circuit and input to an intermediate frequency conversion circuit is detected, and a high-frequency amplification circuit is referred to by referring to the detection level. Control of the gain of the AGC circuit, the AGC circuit also operates due to an interfering signal from another station other than the desired received signal, thereby suppressing the desired received signal level. Signals and noises are also output, and similarly, there is a drawback that a desired audio output signal is significantly impaired.

[0008]

According to a first aspect of the present invention, there is provided a receiving apparatus for amplifying a received signal input from an antenna and outputting the amplified signal, and for setting a frequency of the received signal output from the high frequency amplifier circuit to a predetermined value. An intermediate frequency conversion circuit that converts the intermediate frequency signal into an intermediate frequency signal and outputs the intermediate frequency signal as an intermediate frequency signal, a band-pass filter (hereinafter abbreviated as BPF) formed by applying the intermediate frequency signal to a band pass, and amplifies the intermediate frequency signal. In the receiving device including at least an intermediate frequency amplification and detection circuit that outputs a predetermined desired signal,
When an adjacent interfering signal is present, an intermediate frequency signal at the input terminal of the BPF and an intermediate frequency signal at the output terminal are input, and the intermediate frequency signal corresponding to the interfering signal level is processed through an arithmetic process on a difference signal between the two intermediate frequency signals. An interference signal detection circuit that generates and outputs a specific gain control signal and controls the gain of the high-frequency circuit by the specific gain control signal , wherein the interference signal detection circuit is connected to an input terminal of the BPF.
Between the intermediate frequency signal at the output and the intermediate frequency signal at the output
A difference detection circuit for detecting and outputting the minute,
The differential output of the road is input, the differential output level is detected,
The difference detection level is output as the specific gain control signal.
At the input terminal of the BPF.
A second level for detecting and outputting the signal level of the intermediate frequency signal
A level detection circuit and an intermediate circuit at an output terminal of the BPF.
Level detection for detecting and outputting the signal level of the wave signal
Output circuit and detection of the second and third level detection circuits
Enter the level and specify according to the difference between the two detection levels.
An interference wave type detection circuit that outputs a switching control signal of
A specific gain control signal output from the first level detection circuit
Signal is controlled by the specific switching control signal.
To switch whether or not to output the specific gain control signal.
And an output switching circuit for performing operations .

A receiving apparatus according to a second aspect of the present invention provides a high-frequency amplifier circuit for amplifying and outputting a received signal input from an antenna, and setting the frequency of the received signal output from the high-frequency amplifier circuit to a predetermined intermediate frequency. An intermediate frequency conversion circuit that converts the intermediate frequency signal and outputs it as an intermediate frequency signal, and a band filter (hereinafter referred to as B
Abbreviated as PF), an intermediate frequency signal is amplified and detected, and in a receiving apparatus including at least an intermediate frequency amplifying / detecting circuit that outputs a predetermined desired signal, the gain is controlled by a specific gain control signal. A variable amplifier circuit for amplifying and outputting a desired signal output from the intermediate frequency amplification / detection circuit, and an intermediate frequency signal at an input terminal and an intermediate frequency signal at an output terminal of the BPF when an adjacent interference signal is present. Generating and outputting the specific gain control signal corresponding to the interference signal level through arithmetic processing on the difference signal between these two intermediate frequency signals, and controlling the gain of the variable amplifier circuit by the specific gain control signal. And an interference signal detection circuit for controlling the BP signal.
The intermediate frequency signal at the input of F and the intermediate at the output
A difference detection circuit that detects and outputs a difference from the frequency signal,
The difference output of the difference detection circuit is input and the difference output level
And the difference detection level is determined by the specific gain control signal.
A level detection circuit for outputting the signal as a signal,
The signal level of the intermediate frequency signal at the input
A second level detection circuit for outputting, and an output terminal of the BPF
And output the signal level of the intermediate frequency signal at
A third level detection circuit, and the second and third levels;
Input the detection level of the detection circuit and calculate the difference between the two detection levels.
Correspondingly, an interference wave type detection that outputs a specific switching control signal
Output circuit and a characteristic output from the first level detection circuit.
Input a constant gain control signal, and
Output the specific gain control signal
An output switching circuit for performing a switching operation of
It is characterized by being.

[0010]

[0011] The interference signal detection circuit may be configured to control the BP
A first difference detection circuit for detecting and outputting a difference between the signal level of the intermediate frequency signal at the input terminal of F and the signal level of the intermediate frequency signal at the output terminal, and inputting the difference output of the first difference detection circuit A first level detection circuit for detecting and outputting the differential output level, and a second level detection circuit for detecting and outputting the signal level of the intermediate frequency signal at the output terminal of the BPF.
And a second level detecting circuit for inputting detection levels of the first and second level detection circuits, detecting a difference between the two detection levels, and outputting the difference detection level as the specific gain control signal. And a difference detection circuit for detecting and outputting a difference between the signal level of the intermediate frequency signal at the input terminal of the BPF and the signal level of the intermediate frequency signal at the output terminal of the BPF. A difference detection circuit, a first level detection circuit that receives a difference output of the first difference detection circuit, detects and outputs a difference output level, and calculates a signal level of an intermediate frequency signal at an input terminal of the BPF. A second level detection circuit for detecting and outputting the signal; a third level detection circuit for detecting and outputting the signal level of the intermediate frequency signal at the output terminal of the BPF; and the first and third level detection circuits. A second difference detection circuit that inputs a detection level of the circuit, detects a difference between the two detection levels, and generates and outputs the specific gain control signal defined corresponding to the difference detection level; An interference wave type detection circuit that receives detection levels of the second and third level detection circuits and generates and outputs a specific switching control signal in response to a level difference between the two detection levels; An output switching circuit that receives the specific switching control signal output from the difference detection circuit and is controlled by the switching control signal to perform an output switching operation as to whether or not to output the specific gain control signal. It may be provided.

[0012] Further, the interference signal detection circuit may be configured so that the BP
A first difference detection circuit for detecting and outputting a difference between the intermediate frequency signal at the input terminal of F and the intermediate frequency signal at the output terminal; and a differential output of the first differential detection circuit for inputting a differential output level. A first gain control signal for detecting and generating and outputting a first gain control signal defined corresponding to the difference detection level;
, A second level detection circuit for detecting and outputting the signal level of the intermediate frequency signal at the input terminal of the BPF, and detecting and outputting the signal level of the intermediate frequency signal at the output terminal of the BPF. A third level detection circuit, a detection level of the first and third level detection circuits is inputted, a difference between the two detection levels is detected, and a second gain defined corresponding to the difference detection level A second difference detection circuit for generating and outputting a control signal; and a detection level of the second and third level detection circuits, and a specific switching control signal corresponding to the level difference between the two detection levels. And an interference wave type detection circuit for generating and outputting the first and second gain control signals, and controlled by the switching control signal to output any of the gain control signals as the specific gain control signal. An output switching circuit that performs whether the output switching operation to may be configured with.

[0013]

Next, the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of the first embodiment of the present invention. As shown in FIG. 1, in the present embodiment, a high-frequency amplifier circuit 2, a tuning circuit 3, a level detection circuit 5, and an intermediate frequency conversion circuit 8 correspond to the antenna input terminal 1 and the audio signal output terminal 14. And BPF10,
Interference signal detection circuit 12 and intermediate frequency amplification / detection circuit 13
And is provided.

In FIG. 1, a reception signal input from an antenna input terminal 1 is input to a high frequency amplifier circuit 2 and amplified, and an output signal thereof is selected and output from a tuning circuit 3 by a desired reception frequency signal 4. , To the intermediate frequency conversion circuit 8. In addition, the reception frequency signal 4
The signal is input to a level detection circuit 5 forming a GC circuit, and its output level is detected. A gain control signal 6 corresponding to the detected level is output and input to the high frequency amplifier circuit 2. On the other hand, in the intermediate frequency conversion circuit 8, the frequency of the reception frequency signal 4 is converted into a predetermined intermediate frequency and output as an intermediate frequency signal 9, which is input to the BPF 10 having the intermediate frequency as the center frequency, and The signal is input to the signal detection circuit 12. The intermediate frequency signal 11 output from the BPF 10 is output to the intermediate frequency amplification / detection circuit 1.
3 is amplified and detected, and an audio signal is output via an audio signal output terminal 14. The intermediate frequency signal 11 output from the BPF 10 is also input to an interference signal detection circuit 12, and if an interference signal is present, the interference signal level is detected by the interference signal detection circuit 12, and the detection is performed. The gain control signal 7 corresponding to the level is output and sent to the high frequency amplifier circuit 2.

When there is no interference signal from an adjacent station or the like, the gain control signal 7 is not output from the interference signal level detection circuit 12 and the level detection circuit 5 Only the output gain control signal 6 is input, and the operation of the receiving apparatus including the AGC function is the same as in the case of the above-described conventional example, and the level of the received signal input from the antenna input terminal 1 varies. On the other hand, the gain control signal 6 output from the level detection circuit 5
A desired audio signal is output from the audio output terminal 14 via the.

When an interference signal from an adjacent station exists, for example, when a 100 kHz detuning interference signal that cannot be removed by the BPF 10 is input, the interference signal detection circuit 12 includes an intermediate frequency conversion circuit. In response to the input of the intermediate frequency signal 9 output from the output signal 8 and the intermediate frequency signal 11 output from the BPF 10, the level of the interference signal is detected, and the gain control signal 7 corresponding to the detected level is generated. It is sent to the circuit 2. Therefore, in this case, the gain of the high-frequency amplifier circuit 2 is controlled and adjusted by the gain control signal 6 output from the level detection circuit 5 and the gain control signal 7 output from the interference signal detection circuit 12. Thus, in the presence of the interference signal, the suppression of the normal reception signal level due to the interference signal by the AGC function is suppressed by the intervention of the gain control signal 7 output from the interference signal detection circuit 12, and
4, an audio signal of a normal level is output, and an improvement in audibility at the audio output terminal 14 due to the interference signal is obtained. FIG. 12A is a graph showing the relationship between the interference signal level and the amplification gain of the harmonic amplification circuit 2 when an interference signal is present, and FIG. 13A shows the interference signal level. And the output level at the audio output terminal 14 is shown as a graph. As is clear from the comparison with FIG. 17A in the above-described conventional example, in this embodiment, it is possible to suppress an unpleasant noise level generated at the audio output terminal 14 by the interference signal. It is understood that

Next, if there is an interference signal whose detuning frequency is 300 kHz, which can be removed by the BPF 10 but cannot be removed by the tuning circuit 3, the interference output from the intermediate frequency conversion circuit 8 The intermediate frequency signal 9 including the signal and the intermediate frequency signal 9 not including the interference signal output from the BPF 10 are input to the interference signal detection circuit 12, and the interference signal level and the desired signal level are compared. The amplification gain in the high-frequency amplifier circuit 2 is controlled according to the level value, thereby preventing a desired signal from being suppressed by an interference signal. In FIG. 12B,
The graph shows the relationship between the level difference between the interference signal level and the desired signal level and the amplification gain of the high-frequency amplifier circuit 2, and the amplification gain of the high-frequency amplifier circuit 2 increases as the interference signal level becomes higher than the desired signal level. Increases. If the amplification gain control action for the high-frequency amplifier circuit 2 is set to cancel the amplification gain control action when the level detection circuit 5 intervenes with the interference signal in FIG. 1, the sensitivity suppression disturbance due to the interference signal is improved. You. FIG. 13B is a graph showing the relationship between the interference signal level and the output level at the audio output terminal 14. As the level of the interference signal increases, the noise level increases due to the interference signal. However, the noise level is lower than the level of the desired signal, and the desired signal itself is not suppressed. The deterioration of the noise in this case is determined by the input dynamic range in the high-frequency amplifier 2 and the tuning circuit 3 and the like.

Next, the operation of the interference signal detection circuit 12 will be specifically described. FIG. 2 is a block diagram showing the configuration of the first embodiment of the interference signal detection circuit 12, and the BPF 1
0, the signal level of the intermediate frequency signal 9 and BP
A difference detection circuit 15 that detects and outputs an interference signal component 17 corresponding to a difference in signal level of the intermediate frequency signal 11 output from the F10, and an interference signal component 17 output from the difference detection circuit 15 A level detection circuit 16 for detecting the level of the signal component 17 and outputting the gain control signal 7 corresponding to the detected level. In the following description of the operation, the frequency characteristics of the intermediate frequency signal at the input end and the output end of the BPF 10 shown in FIGS. 8A and 8B, respectively, and the difference detection shown in FIG. With reference to the frequency characteristics of the disturbing signal component 17 output from the circuit 15, the operation will be described in the case where there is a disturbing signal having a detuning frequency ± 100 kHz that cannot be removed by the BPF 10.

In FIG. 2, as described above, the BPF 10
Detuning frequency ± 100 kHz that cannot be removed by
When an interference signal of z exists, the passband width of the tuning circuit 3 is wide, so that the frequency component of the intermediate frequency signal 9 at the input terminal of the BPF 10 has a desired value as shown in FIG. An interference signal 100 kHz adjacent to the signal exists. The intermediate frequency signal 9 is input to the difference detection circuit 15 included in the interference signal detection circuit 12, and is also input to the BPF 10. The frequency component of the intermediate frequency signal 11 at the output end of the BPF 10
Since the signal cannot be completely removed by F10, as shown in FIG. 8B, the signal remains at a considerable level with respect to the desired signal.
The signal is input to a detection circuit 13 and a difference detection circuit 15 included in the interference signal detection circuit 12. In the difference detection circuit 15, the difference between the intermediate frequency signals 9 and 11 at the input and output ends of the BPF 10 is obtained, and as shown in FIG.
Is input to

FIG. 10 is a block diagram showing an example of the configuration of the difference detection circuit 15. The amplifier 31 corrects the level of a desired signal attenuated by the BPF 10, an operational amplifier 32, and resistors 25, 26 and 27. It is composed of a subtractor formed. In FIG. 10, the amplifier 31
In the intermediate frequency signal 11 whose level has been corrected in the above, a difference from the intermediate frequency signal 9 is obtained through a subtraction circuit composed of an operational amplifier 32 and resistors 25, 26 and 27, and a desired signal component is removed to correspond to the difference. Is output. In the level detection circuit 16, the signal level of the interference signal component 17 is detected, and the gain control signal 7 corresponding to the detection level of the interference signal is generated and output. The gain control signal 7 controls the amplification gain of the high-frequency amplifier circuit 2. The difference detection circuits included in the second, third, fourth and fifth embodiments of the interference signal detection circuit 12 described below are all shown in FIG.
This is due to the configuration shown in FIG.

The first of the above interference signal level detection circuits 12
In the embodiment, the band characteristic of the tuning circuit 3 can be improved by adding / adjusting the coil and the capacitance constituting the tuning circuit 3, and the adjacent interference signal of about 200 kHz to 300 kHz can be removed. . Thereby, B
100 kHz that cannot be removed in PF10
Works effectively when the adjacent interfering signal becomes a problem.

FIG. 3 is a block diagram showing the configuration of the second embodiment of the interference signal detection circuit 12. The difference between the intermediate frequency signal 9 and the intermediate frequency signal 11 output from the BPF 10 corresponding to the BPF 10 is shown in FIG. A difference detection circuit 15 for detecting and outputting the corresponding interference signal component 17, level detection circuits 19 and 18 for detecting and outputting the levels of the intermediate frequency signals 9 and 11, respectively, and level detection for the level detection circuits 19 and 18. Upon receiving the signals 40 and 41, the type of the interference wave is detected and a predetermined switching control signal 42 is output, and the interference signal component 17 output from the difference detection circuit 15 is output. The level of the component 17 is detected, and the gain control signal 7 corresponding to the detected level is detected.
A level detection circuit 16 for outputting the gain control signal 7
And an output switching circuit 21 that outputs the gain control signal 7 through the ON / OFF control action of the switching control signal 42. This interference signal detection circuit 12
In the second embodiment of FIG. 1, a 100 kHz adjacent interference signal which cannot be removed by the BPF 10 is shown in FIG.
Unable to remove in tuning circuit 3 ~ 300k
Hz adjacent interference signal is present, the BPF 10
This is an application example of a disturbance signal level detection circuit that enables perceptual correction at the audio output terminal 14 for a disturbance signal adjacent to 100 kHz that cannot be removed in the above.

The following second signal of the interference signal detection circuit 12 is used.
The operation of this embodiment will be described with reference to FIGS.
FIG. 8 when there is an adjacent interference signal of 0 kHz.
(A) and the input terminal of the BPF 10 shown in (b),
The frequency characteristics of the intermediate frequency signals 9 and 11 at the output end, the frequency characteristics of the interference signal component 17 output from the difference detection circuit 15 shown in FIG.
FIG. 9 (a) when the adjacent interference signal of z exists
And (b) frequency characteristics of the intermediate frequency signals 9 and 11 at the input end and the output end of the BPF 10,
This is performed by referring to the frequency characteristics of the interference signal component 17 output from the difference detection circuit 15 shown in FIG.

In FIG. 3, the interference signal component 17 output from the difference detection circuit 15 is input to a level detection circuit 16, and the level detection circuit 16 outputs a gain control signal 7 corresponding to the detection level of the interference signal. Then, it is input to the output switching circuit 21. In this case, as the output from the difference detection circuit 15, if there is a 100 kHz adjacent interference signal that cannot be removed by the BPF 10,
In any case where there is an adjacent interference signal at the same frequency, the interference signal component 17 is output in the same manner. Therefore, regarding the amplification gain control for the high-frequency amplifier circuit 2 corresponding to the interference signal level, the interference signal is It is necessary to determine whether the signal is an interference signal that can be removed by the BPF 10 or an interference signal that cannot be removed, and control the amplification gain of the high-frequency amplifier circuit 2 in FIG. The determination as to whether or not it can be removed by the BPF 10 can be made by the BPF 10 as is clear with reference to FIGS. 8A and 8B and FIGS. 9A and 9B. In the case of a possible interference signal (see FIG. 9), the difference between the signal levels (average values) of the intermediate frequency signals 9 and 11 at the input terminal and the output terminal of the BPF 10 is clear, but the difference is removed by the BPF 10. In the case of an interfering signal (see FIG. 8) that cannot be performed, the intermediate frequency signals 9 and 11 at the input terminal and the output terminal of the BPF 10 are output.
Is not remarkable as compared with the case where the BPF 10 can remove the signal level (average value). This allows
The signal level of the intermediate frequency signal 9 at the input end of the BPF 10 (the input level to the level detection circuit 19),
By comparing the signal level of the intermediate frequency signal 11 (the input level to the level detection circuit 18) at the output terminal of the F10, it is determined whether the interference signal can be eliminated by the BPF 10 or the interference cannot be eliminated. It can be determined whether the signal is a signal. That is,
In the level detection circuits 19 and 18, the level detection signals 40 and 41 corresponding to the detected intermediate frequency signals 9 and 11, respectively, are input to the interference wave type detection circuit 20, compared and collated, and the above-described determination operation is performed. . In fact, the level of the interfering signal that can be removed in the BPF 10 has a significant effect (greater than 10 dB) on the desired signal, which adversely affects the desired signal.
This is when there is a level interference signal, and in such a case, the level difference between the signal level of the intermediate frequency signal 9 at the input terminal of the BPF 10 and the signal level of the intermediate frequency signal 11 at the output terminal of the BPF 10 is obvious. And

FIG. 11 shows a specific circuit example of the interference wave type detection circuit 20 in FIG. 3, which includes a subtractor formed by an operational amplifier 38, resistors 35, 36 and 37, and a reference voltage source. (Reference voltage: Vc) 34 and a comparator 39 for comparing the output of the subtractor with the reference voltage Vc of the reference voltage source 34. The value of the reference voltage Vc of the reference voltage source 34 is appropriately set according to the level detection characteristics of the level detection circuits 19 and 18 in FIG. In this interfering wave type detecting circuit 20, the level difference between the level detecting signal 40 and the level detecting signal 41 is large for the interfering signal which can be removed by the BPF 10 shown in FIG.
8 has a value lower than the reference voltage Vc. In this case, the switching control signal 4 output from the comparator 39
2 is output as a control signal for turning off the output switching circuit 21. Thus, the gain of the high-frequency amplifier circuit 2 in FIG. 1 is controlled and adjusted by the gain control signal 7 for an adjacent interference signal of 100 kHz that cannot be removed by the BPF 10.

FIG. 4 is a block diagram showing the configuration of a third embodiment of the interference signal detecting circuit 12, and the BPF 10
, A difference detection circuit 15 for detecting and outputting an interference signal component 17 corresponding to the difference between the intermediate frequency signal 9 at the input end of the BPF 10 and the intermediate frequency signal 11 at the output end, and output from the difference detection circuit 15. A level detection circuit 16 for receiving the interference signal component 17 and detecting the interference signal level, and an intermediate frequency signal 11 at the output terminal of the BPF 10.
A level detection circuit 18 for detecting the signal level of the level detection signal, a difference detection circuit 23 for receiving the level detection signals 43 and 44 output from the level detection circuits 16 and 18 and detecting a difference between the two level detection signals. It is comprised including. A third embodiment of the interference signal detection circuit 12 is as follows.
FIG. 1 is an embodiment applied only to adjacent interference signals of 200 kHz to 300 kHz which can be removed by the BPF 10, and is formed by a coil and a capacitor instead of a ceramic filter generally used as the BPF 10. This is effective when BPF is used.

In FIG. 4, 200 kHz to 300 kHz
When there is an adjacent interference signal of z, the frequency component of the intermediate frequency signal 9 at the input terminal of the BPF 10 (FIG. 9A)
9), the frequency component of the intermediate frequency signal 11 at the output end of the BPF 10 (see FIG. 9 (b)) has only the frequency component of the desired signal after the interference signal has been removed. The detection circuit 15 outputs the interference signal component 17
(See FIG. 9C) only. In response to the interference signal component 17, the level detection circuit 16 detects the level of the interference signal, outputs the signal level 43 of the interference signal, and inputs the signal level 43 to the difference detection circuit 23. On the other hand, the intermediate frequency signal 11 at the output terminal of the BPF 10 is also input to the level detection circuit 18, where the intermediate frequency signal 11, ie, FIG.
The signal level of the desired signal component from which the interfering signal shown in (b) has been removed is detected, and the signal level of the desired signal 4
4 is output and input to the difference detection circuit 23. The difference detection circuit 23 receives the input of the signal level 43 of the interference signal and the signal level 44 of the desired signal,
The comparison and comparison of both signal levels are performed, and a gain control signal 7 corresponding to the comparison result is output, and the amplification gain control for the high-frequency amplifier circuit 2 in FIG. 1 is performed. Note that the difference detection circuit 23 in this case can be realized in the same manner as the circuit shown in FIG. 10 described above, and in FIG. Can be set so as not to affect the desired signal. Thus, it is possible to prevent the audio output terminal 14 from suppressing the audio signal output due to the interference signal.

FIG. 5 is a block diagram showing the configuration of the fourth embodiment of the interference signal detection circuit 12. The intermediate frequency signal 9 at the input terminal of the BPF 10 and the intermediate frequency signal 11 at the output terminal thereof correspond to the BPF 10. A difference detection circuit 15 that detects and outputs an interference signal component 17 corresponding to the difference
A level detection circuit 1 that receives the interference signal component 17 output from the difference detection circuit 15 and detects the interference signal level
6, a level detection circuit 19 for detecting the signal level of the intermediate frequency signal 9 at the input terminal of the BPF 10, a level detection circuit 18 for detecting the signal level of the intermediate frequency signal 11 at the output terminal of the BPF 10, and these level detection circuits 19 and 18
Receiving the level detection signals 40 and 41 output from the CPU, detects the type of the interference wave, and outputs a predetermined switching control signal 42
An interference wave type detection circuit 20 (see FIG. 11) that outputs
Upon receiving the level detection signals 43 and 41 output from the level detection circuits 16 and 18, a difference detection circuit 23 that detects a difference between the two level detection signals, and an interference corresponding to the difference detected by the difference detection circuit 23. An output switching circuit 21 that receives a signal level of a signal, is switched and controlled by a switching control signal 42, and outputs the signal as a gain control signal 7 to the high-frequency amplifier circuit 2.

In this embodiment, in FIG. 1, a 100 kHz adjacent interfering signal that cannot be removed by the BPF 10 and that cannot be removed by the tuning circuit 3
When there is a 300 kHz adjacent interference signal, the BPF
10 is an example in which it is possible to improve the suppression effect due to the adjacent interference signal of up to 300 kHz which can be removed by the method of FIG. The operation of the interference signal detection circuit 12 in this embodiment is the same as that of the second embodiment shown in FIG. 3 and the third embodiment shown in FIG. A signal is determined, and the output switching circuit 21 outputs B
The gain control signal 7 corresponding to only the level of the interference signal that can be removed by the PF 10 is output, the amplification gain of the high-frequency amplifier circuit 2 is controlled, and the characteristics are improved as shown in FIG. Will be

FIG. 6 is a block diagram showing the configuration of a fifth embodiment of the interference signal detection circuit 12. The intermediate frequency signal 9 at the input terminal of the BPF 10 and the intermediate frequency signal 11 at the output terminal thereof correspond to the BPF 10. A difference detection circuit 15 that detects and outputs an interference signal component 17 corresponding to the difference
A level detection circuit 1 that receives the interference signal component 17 output from the difference detection circuit 15 and detects the interference signal level
6, a level detection circuit 19 for detecting the signal level of the intermediate frequency signal 9 at the input terminal of the BPF 10, a level detection circuit 18 for detecting the signal level of the intermediate frequency signal 11 at the output terminal of the BPF 10, and these level detection circuits 19 and 18
Receiving the level detection signals 40 and 41 output from the CPU, detects the type of the interference wave, and outputs a predetermined switching control signal 42
An interference wave type detection circuit 20 (see FIG. 11) that outputs
Upon receiving the level detection signals 43 and 41 output from the level detection circuits 16 and 18, a difference detection circuit 23 that detects a difference between the two level detection signals, and an interference corresponding to the difference detected by the difference detection circuit 23. The signal level 44 of the signal and the level detection signal 43 output from the level detection circuit 16 are input, and controlled by the switching control signal 42, to output the gain control signal 7 corresponding to one of the interference signal levels. An output switching circuit 24 is provided.

This embodiment is an embodiment capable of coping with both cases where the interfering signal can be removed by the BPF 10 and the case where it cannot be removed in FIG. As in the above-described second and fourth embodiments, the interference wave type detection circuit 20 determines whether or not the interference signal can be removed by the BPF 10 and cannot remove the interference signal. Is determined by the switching control signal 42 output from the interference wave type detection circuit 20, and the difference detection circuit 15 is controlled in the same manner as in the second embodiment shown in FIG.
The gain control signal 7 corresponding to the level detection signal 43 output via the level detection circuit 16 is selected and output, and sent to the high frequency amplifier circuit 2. This allows
The audibility correction at the audio output terminal 14 is effectively performed corresponding to the adjacent interference signal whose interference signal cannot be removed by the BPF 10. Conversely, if the interference signal is BP
If it is determined in F10 that the signal can be removed, the level detection signal output via the level detection circuit 18 and the difference detection circuit 23 is used as in the case of the third embodiment shown in FIG. The gain control signal 7 corresponding to 44 is selected and output, and sent to the high frequency amplifier circuit 2. Accordingly, the audibility correction at the audio output terminal 14 is effectively performed corresponding to the adjacent interference signal from which the interference signal can be removed by the BPF 10.

Next, a description will be given of a second embodiment of the receiving apparatus according to the present invention. FIG. 7 is a block diagram showing the configuration of the present embodiment. As shown in FIG. 7, the present embodiment corresponds to the antenna input terminal 1 and the audio signal output terminal 14,
High frequency amplifier circuit 2, tuning circuit 3, and level detection circuit 5
, An intermediate frequency conversion circuit 8, a BPF 10, an interference signal detection circuit 12, an intermediate frequency amplification / detection circuit 13, and a variable amplification circuit 28. The difference between the present embodiment and the first embodiment is that in this embodiment, a variable amplifying circuit 28 is added at a stage subsequent to the intermediate frequency amplifying / detecting circuit 13, and an output from the interference signal level detecting circuit 12 is provided. The gain control signal 7 is not transmitted to the high-frequency amplifier circuit 2,
This means that the signal is input to the variable amplifier circuit 28 and the amplification gain is controlled.

In FIG. 7, a reception signal input from an antenna input terminal 1 is input to a high-frequency amplifier circuit 2 and amplified, and an output signal thereof is selected and output from a tuning circuit 3 by a desired reception frequency signal 4. , To the intermediate frequency conversion circuit 8. In addition, the reception frequency signal 4
The signal is input to a level detection circuit 5 forming a GC circuit, and its output level is detected. A gain control signal 6 corresponding to the detected level is output and input to the high frequency amplifier circuit 2. On the other hand, in the intermediate frequency conversion circuit 8, the frequency of the reception frequency signal 4 is converted into a predetermined intermediate frequency and output as an intermediate frequency signal 9, which is input to the BPF 10 having the intermediate frequency as the center frequency, and The signal is input to the signal detection circuit 12. The intermediate frequency signal 11 output from the BPF 10 is output to the intermediate frequency amplification / detection circuit 1.
3 and amplified and detected, and the output signal 22 is input to the variable amplifier circuit 28. The intermediate frequency signal 11 output from the BPF 10 is also input to an interference signal detection circuit 12, and if an interference signal is present, the interference signal level is detected by the interference signal detection circuit 12, and the detection is performed. The gain control signal 7 corresponding to the level is output and input to the variable amplifier circuit 28. Variable amplification circuit 28
In, the amplification gain is controlled by the gain control signal 7, the interference signal component included in the output signal 22 is relatively suppressed, and a desired audio signal is output via the audio signal output terminal 14. The configuration and operation of the interference signal detection circuit 12 are formed in accordance with the first embodiment.
This is the same as the first, second, third, fourth and fifth embodiments of the interference signal detection circuit 12.

In this embodiment, there is an interference of an adjacent station,
100 kHz that cannot be removed in BPF10
When there is an adjacent interference signal of z, the interference signal level is detected by the interference signal detection circuit 12, and the gain control signal 7 corresponding to the interference signal level causes the gain control signal 7 shown in FIG.
As shown in FIG. 13C, the amplification gain of the variable amplifier circuit 28 is controlled, and as shown in FIG. 13B, the noise level of the audio signal at the audio signal output terminal 14 can be suppressed. If there is an adjacent interfering signal of up to 300 kHz, which can be removed by the BPF 10 but cannot be removed by the tuning circuit 3, the interfering signal detection circuit 12 detects the interfering signal level and The gain control signal 7 corresponding to the signal level controls the amplification gain of the variable amplifier circuit 28 as shown in FIG.
As shown in (1), it is possible to suppress the level of the interference signal for the audio signal at the audio signal output terminal 14.

[0036]

As described above, according to the present invention, the difference between the intermediate frequency signal at the input terminal of the intermediate frequency band-pass filter (BPF) and the intermediate frequency signal at the output terminal in the presence of the adjacent interfering signal. The type and level of the disturbing signal are determined from the signal, and the gain of one of the high-frequency amplifier circuit and the amplifier circuit of the detection signal output stage is determined by the gain control signal corresponding to the disturbing signal level generated based on the determination result. By performing the control, it is possible to improve the audibility of an interference signal that cannot be removed by the BPF, and to prevent a level suppression effect on a desired signal due to the interference signal that can be removed by the BPF. effective.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a first embodiment of a disturbance signal detection circuit included in the present invention.

FIG. 3 is a block diagram showing a configuration of a second embodiment of the interference signal detection circuit included in the present invention.

FIG. 4 is a block diagram showing a configuration of a third embodiment of a disturbance signal detection circuit included in the present invention.

FIG. 5 is a block diagram showing the configuration of a fourth embodiment of the interference signal detection circuit included in the present invention.

FIG. 6 is a block diagram showing a configuration of a fifth embodiment of a disturbance signal detection circuit included in the present invention.

FIG. 7 is a block diagram illustrating a configuration of a second exemplary embodiment of the present invention.

FIG. 8 is a diagram showing a desired signal component and a disturbing signal component at an input / output terminal of a BPF.

FIG. 9 is a diagram illustrating a desired signal component and a disturbing signal component at an input / output terminal of a BPF.

FIG. 10 is a block diagram illustrating a configuration of an example of a difference detection circuit.

FIG. 11 is a block diagram illustrating a configuration of an example of an interference wave type detection circuit.

FIG. 12 is a diagram illustrating gain characteristics of a high-frequency amplifier circuit and a variable amplifier circuit corresponding to an interference signal level.

FIG. 13 is a diagram illustrating an output level characteristic corresponding to an interference signal level.

FIG. 14 is a block diagram showing a configuration of a conventional example.

FIG. 15 is a diagram illustrating frequency characteristics of a BPF.

FIG. 16 is a diagram illustrating a frequency characteristic of the tuning circuit.

FIG. 17 is a diagram showing an output level characteristic corresponding to an interference signal level in a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Antenna input terminal 2 High frequency amplifier circuit 3 Tuning circuit 5, 16, 18, 19 Level detection circuit 8 Intermediate frequency conversion circuit 10 BPF 12 Interference signal detection circuit 13 Intermediate frequency amplification / detection circuit 14 Audio signal output terminal 15, 23 Difference detection Circuit 20 Interference wave type detection circuit 21, 24 Output switching circuit 25 to 27 Resistance 28 Variable amplifier circuit 31 Amplifier 32 Operational amplifier 34 Reference voltage source 35 to 37 Resistance 38 Operational amplifier 39 Comparative circuit

Claims (8)

(57) [Claims] 1. A high-frequency amplifier circuit for amplifying and outputting a received signal input from an antenna, and converting a frequency of the received signal output from the high-frequency amplifier circuit to a predetermined intermediate frequency and outputting the intermediate frequency signal as an intermediate frequency signal An intermediate frequency conversion circuit, a band-pass filter (hereinafter abbreviated as BPF) formed with the intermediate frequency signal as a band-pass target, an intermediate frequency signal for amplifying and detecting the intermediate frequency signal, and outputting a predetermined desired signal. A receiving apparatus comprising at least a frequency amplifying / detecting circuit, wherein an intermediate frequency signal at an input terminal and an intermediate frequency signal at an output terminal of the BPF are input when an adjacent interfering signal is present, and a difference signal between the two intermediate frequency signals is input. A specific gain control signal corresponding to the interference signal level is generated and output through an arithmetic process for Comprising a disturbing signal detecting circuit for controlling the gain of the circuit, the interference signal detection circuit, at the input of the BPF
The difference between the intermediate frequency signal and the intermediate frequency signal at the output
A difference detection circuit for detecting and outputting, and a difference output level for inputting a difference output of the difference detection circuit.
And the difference detection level is determined by the specific gain control signal.
And a signal level of an intermediate frequency signal at an input terminal of the BPF.
And a signal level of an intermediate frequency signal at an output terminal of the BPF.
And a third level detection circuit for detecting and outputting the detection level, and inputting the detection levels of the second and third level detection circuits.
Specific switching control according to the difference between the two detection levels.
An interference wave type detection circuit for outputting a signal, and a specific gain control output from the first level detection circuit.
Control signal, and controlled by the specific switching control signal.
Switch whether to output the specific gain control signal.
Receiving device comprising an output switching circuit for performing an operation, to be configured with. 2. A high-frequency amplifier circuit for amplifying and outputting a received signal input from an antenna, and converting a frequency of the received signal output from the high-frequency amplifier circuit to a predetermined intermediate frequency and outputting the intermediate frequency signal as an intermediate frequency signal An intermediate frequency conversion circuit, a band-pass filter (hereinafter abbreviated as BPF) formed with the intermediate frequency signal as a band-pass target, an intermediate frequency signal for amplifying and detecting the intermediate frequency signal, and outputting a predetermined desired signal. A receiving apparatus comprising at least a frequency amplification / detection circuit, a variable amplification circuit whose gain is controlled by a specific gain control signal and amplifies and outputs a desired signal output from the intermediate frequency amplification / detection circuit; , The intermediate frequency signal at the input terminal of the BPF and the intermediate frequency signal at the output terminal are input, and the difference signal between these two intermediate frequency signals is Said generating and outputting said specific gain control signal corresponding to the interference signal level through that processing, and a disturbing signal detecting circuit for controlling the gain of the variable amplification circuit by the specific gain control signal , The interference signal detection circuit is connected to the input terminal of the BPF.
The difference between the intermediate frequency signal and the intermediate frequency signal at the output
A difference detection circuit for detecting and outputting, and a difference output level for inputting a difference output of the difference detection circuit.
And the difference detection level is determined by the specific gain control signal.
And a signal level of an intermediate frequency signal at an input terminal of the BPF.
And a signal level of an intermediate frequency signal at an output terminal of the BPF.
And a third level detection circuit for detecting and outputting the detection level, and inputting the detection levels of the second and third level detection circuits.
Specific switching control according to the difference between the two detection levels.
An interference wave type detection circuit for outputting a signal, and a specific gain control output from the first level detection circuit.
Control signal, and controlled by the specific switching control signal.
Switch whether to output the specific gain control signal.
Receiving device comprising an output switching circuit for performing an operation, to be configured with. 3. Amplifying a received signal input from an antenna.
High-frequency amplifier circuit that outputs the
Frequency of the received signal to be output to a predetermined intermediate frequency.
Intermediate frequency conversion circuit for converting and outputting as an intermediate frequency signal
And the intermediate frequency signal is formed as a band-pass target.
Bandpass filter (hereinafter abbreviated as BPF) and the intermediate
Amplifies and detects frequency signals and outputs the desired signal
Receiver having at least an intermediate frequency amplification / detection circuit
At the input of the BPF when there is an adjacent interfering signal
Input intermediate frequency signal and intermediate frequency signal at output terminal
And processing the difference signal between these two intermediate frequency signals.
Specific gain control corresponding to the disturbing signal level via
Generate and output a signal, and use the specific gain control signal
A disturbance signal detection circuit for controlling the gain of the high-frequency circuit.
The interference signal detection circuit is connected to an input terminal of the BPF.
The signal level of the intermediate frequency signal and the intermediate frequency signal at the output end
1st difference which detects and outputs the difference with the signal level of the signal
A detection circuit, and a difference output of the first difference detection circuit
A first level detection circuit for detecting and outputting a level, and a signal level of an intermediate frequency signal at an output terminal of the BPF
And a second level detection circuit for detecting and outputting the detection level, and inputting the detection levels of the first and second level detection circuits.
To detect the difference between the two detection levels and detect the difference.
A second level for outputting a level as the specific gain control signal.
Receiving apparatus characterized by being configured to include a difference detection circuit. 4. Amplifying a received signal input from an antenna.
High-frequency amplifier circuit that outputs the
Frequency of the received signal to be output to a predetermined intermediate frequency.
Intermediate frequency conversion circuit for converting and outputting as an intermediate frequency signal
And the intermediate frequency signal is formed as a band-pass target.
Bandpass filter (hereinafter abbreviated as BPF) and the intermediate
Amplifies and detects frequency signals and outputs the desired signal
Receiver having at least an intermediate frequency amplification / detection circuit
In the gain control by a specific gain control signal, the intermediate frequency
Amplify and output the desired signal output from the amplification / detection circuit
At the input end of the BPF when there is an adjacent interfering signal.
Input intermediate frequency signal and intermediate frequency signal at output terminal
And processing the difference signal between these two intermediate frequency signals.
The specific gain corresponding to the disturbing signal level via
A control signal is generated and output, and the specific gain control signal is
A disturbance signal detection circuit for controlling the gain of the variable amplifier circuit.
And the disturbance signal detection circuit is provided at an input end of the BPF.
The signal level of the intermediate frequency signal and the intermediate frequency signal at the output end
1st difference which detects and outputs the difference with the signal level of the signal
A detection circuit, and a difference output of the first difference detection circuit
A first level detection circuit for detecting and outputting a level, and a signal level of an intermediate frequency signal at an output terminal of the BPF
And a second level detection circuit for detecting and outputting the detection level, and inputting the detection levels of the first and second level detection circuits.
To detect the difference between the two detection levels and detect the difference.
A second level for outputting a level as the specific gain control signal.
Receiving apparatus characterized by being configured to include a difference detection circuit. 5. Amplifying a received signal input from an antenna.
High-frequency amplifier circuit that outputs the
Frequency of the received signal to be output to a predetermined intermediate frequency.
Intermediate frequency conversion circuit for converting and outputting as an intermediate frequency signal
And the intermediate frequency signal is formed as a band-pass target.
Bandpass filter (hereinafter abbreviated as BPF) and the intermediate
Amplifies and detects frequency signals and outputs the desired signal
Receiver having at least an intermediate frequency amplification / detection circuit
At the input of the BPF when there is an adjacent interfering signal
Input intermediate frequency signal and intermediate frequency signal at output terminal
And processing the difference signal between these two intermediate frequency signals.
Specific gain control corresponding to the disturbing signal level via
Generate and output a signal, and use the specific gain control signal
A disturbance signal detection circuit for controlling the gain of the high-frequency circuit.
The interference signal detection circuit is connected to an input terminal of the BPF.
The signal level of the intermediate frequency signal and the intermediate frequency signal at the output end
1st difference which detects and outputs the difference with the signal level of the signal
A detection circuit, and a difference output of the first difference detection circuit
A first level detection circuit you detect and output level, the signal level of the intermediate frequency signal at the input of the BPF
And a signal level of an intermediate frequency signal at an output terminal of the BPF.
And a third level detection circuit for detecting and outputting the detection level, and inputting the detection levels of the first and third level detection circuits.
To detect the difference between the two detection levels and detect the difference.
The specific gain control signal defined corresponding to the level
A second difference detection circuit for generating and outputting, and the detection levels of the second and third level detection circuits are input.
Specific level corresponding to the level difference between the two detection levels.
Interference wave type detection circuit that generates and outputs a switching control signal
And the specific switching output from the second difference detection circuit
Input a control signal, controlled by the switching control signal
To output the specific gain control signal.
Receiving apparatus characterized by being configured to include an output switching circuit for performing replacement operation, the. 6. Amplifying a received signal input from an antenna.
Output from the high-frequency amplifier circuit and the high-frequency amplifier circuit
Converts the frequency of the received signal output to a predetermined intermediate frequency
And an intermediate frequency conversion circuit that outputs the signal as an intermediate frequency signal
And the intermediate frequency signal is formed as a band-pass target.
Bandpass filter (hereinafter abbreviated as BPF) and the intermediate
Amplifies and detects frequency signals and outputs the desired signal
Receiver having at least an intermediate frequency amplification / detection circuit
In the gain control by a specific gain control signal, the intermediate frequency
Amplify and output the desired signal output from the amplification / detection circuit
At the input end of the BPF when there is an adjacent interfering signal.
Input intermediate frequency signal and intermediate frequency signal at output terminal
And processing the difference signal between these two intermediate frequency signals.
The specific gain corresponding to the disturbing signal level via
A control signal is generated and output, and the specific gain control signal is
A disturbance signal detection circuit for controlling the gain of the variable amplifier circuit.
Comprising a road, wherein the disturbing signal detecting circuit, the first differential detection circuit for detecting the difference between the signal level of the intermediate frequency signal and outputs the signal level and the output end of the intermediate frequency signal at the input of the BPF A first level detection circuit that receives a difference output of the first difference detection circuit, detects and outputs a difference output level, and detects and outputs a signal level of an intermediate frequency signal at an input terminal of the BPF. A second level detection circuit, a third level detection circuit that detects and outputs a signal level of an intermediate frequency signal at an output terminal of the BPF, and inputs detection levels of the first and third level detection circuits. A second difference detection circuit that detects a difference between the two detection levels and generates and outputs the specific gain control signal defined corresponding to the difference detection level; And an interference wave type detection circuit that generates and outputs a specific switching control signal in accordance with the level difference between the two detection levels, and an output from the second difference detection circuit. The specific switching control signal is input, and the output switching circuit is controlled by the switching control signal and performs an output switching operation of whether or not to output the specific gain control signal. receiving apparatus characterized by that. 7. Amplifying a received signal input from an antenna
High-frequency amplifier circuit that outputs the
Frequency of the received signal to be output to a predetermined intermediate frequency.
Intermediate frequency conversion circuit for converting and outputting as an intermediate frequency signal
And the intermediate frequency signal is formed as a band-pass target.
Bandpass filter (hereinafter abbreviated as BPF) and the intermediate
Amplifies and detects frequency signals and outputs the desired signal
Receiver having at least an intermediate frequency amplification / detection circuit
At the input of the BPF when there is an adjacent interfering signal
Input intermediate frequency signal and intermediate frequency signal at output terminal
And processing the difference signal between these two intermediate frequency signals.
Specific gain control corresponding to the disturbing signal level via
Generate and output a signal, and use the specific gain control signal
A disturbance signal detection circuit for controlling the gain of the high-frequency circuit.
A first difference detection circuit for detecting and outputting a difference between an intermediate frequency signal at an input terminal of the BPF and an intermediate frequency signal at an output terminal of the BPF; A first level detection circuit for receiving a difference output, detecting a difference output level, generating and outputting a first gain control signal defined corresponding to the difference detection level, and an input terminal of the BPF. A second level detection circuit that detects and outputs a signal level of the intermediate frequency signal; a third level detection circuit that detects and outputs a signal level of the intermediate frequency signal at an output terminal of the BPF; A second difference for inputting the detection level of the third level detection circuit, detecting a difference between the two detection levels, generating and outputting a second gain control signal defined corresponding to the difference detection level Inspection An output circuit, and an interference wave type detection circuit that receives the detection levels of the second and third level detection circuits, generates and outputs a specific switching control signal in response to the level difference between the two detection levels, and An output switch for receiving the first and second gain control signals and performing an output switch operation of controlling which gain control signal is output as the specific gain control signal under the control of the switch control signal; A receiving circuit, comprising: a circuit; 8. Amplifying a received signal input from an antenna
High-frequency amplifier circuit that outputs the
Frequency of the received signal to be output to a predetermined intermediate frequency.
Intermediate frequency conversion circuit for converting and outputting as an intermediate frequency signal
And the intermediate frequency signal is formed as a band-pass target.
Bandpass filter (hereinafter abbreviated as BPF) and the intermediate
Amplifies and detects frequency signals and outputs the desired signal
Receiver having at least an intermediate frequency amplification / detection circuit
At The gain is controlled by a specific gain control signal, and the intermediate frequency
Amplify and output the desired signal output from the amplification / detection circuit
Variable amplifier circuit, At the input of the BPF in the presence of an adjacent interfering signal
Input intermediate frequency signal and intermediate frequency signal at output terminal
And processing the difference signal between these two intermediate frequency signals.
The specific gain corresponding to the disturbing signal level via
A control signal is generated and output, and the specific gain control signal is
A disturbance signal detection circuit for controlling the gain of the variable amplifier circuit.
Road and With The interference signal detection circuit is provided at an input terminal of the BPF.
The difference between the intermediate frequency signal and the intermediate frequency signal at the output
A first difference detection circuit for detecting and outputting; Receiving a difference output of the first difference detection circuit and outputting a difference;
Level is detected and specified according to the difference detection level.
A first level for generating and outputting a first gain control signal
Detector circuit, The signal level of the intermediate frequency signal at the input terminal of the BPF
A second level detection circuit for detecting and outputting The signal level of the intermediate frequency signal at the output terminal of the BPF
A third level detection circuit for detecting and outputting The detection levels of the first and third level detection circuits are input.
To detect the difference between the two detection levels and detect the difference.
Generates a second gain control signal defined according to the level
A second difference detection circuit that outputs The detection levels of the second and third level detection circuits are input.
Specific level corresponding to the level difference between the two detection levels.
Interference wave type detection circuit that generates and outputs a switching control signal
When, Receiving the first and second gain control signals,
Controlled by the control signal, any of the gain control signals
Output switching operation whether to output as a specific gain control signal
An output switching circuit for A receiving device comprising: