JP2015220631A - Receiver circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To remove an interference wave if the frequency of the interference wave varies with the lapse of time.SOLUTION: A receiver circuit includes a frequency detection circuit 3 for detecting the reception spectrum of the interference wave which includes higher power than specific power P1 among the reception spectra of signals passing through a band-pass filter 2. A frequency band, which includes a center frequency (fnh) of a reception spectrum detected by the frequency detection circuit 3, is set to a cutoff band B. A variable band rejection filter 4 cuts off the interference wave of the center frequency (fnh) which is included in the radio signal and output from an antenna 1, to pass a signal (signal in a band B' other than the cutoff band B) other than the interference wave.

Description

  The present invention relates to a receiving circuit that extracts a transmission signal from a radio signal mixed with an interference wave.

The receiving circuit disclosed in Non-Patent Document 1 below includes an interference wave removing filter for removing an interference wave mixed in a radio signal in order to extract only a transmission signal from the radio signal. .
The interference wave elimination filter is set in advance with the frequency of the interference wave as a cutoff band, and the filter extracts a transmission signal by passing a signal other than the interference wave included in the radio signal. ing.
However, since the cutoff band of the filter is fixed, the interference wave cannot be removed when the frequency of the interference wave varies with time.

Aarno Parssinen, “DIRECT CONVERSION RECEIVERS IN WIDE-BAND SYSTEMS”, KLUWER ACADEMIC PUBLISHERS, Sep 2001

  Since the conventional receiving circuit is configured as described above, when the frequency of the interference wave varies with time, the interference wave removal filter cannot remove the interference wave. When a radio signal from which interference waves have not been removed is input to a low-noise amplifier installed after the filter, the input power of the low-noise amplifier increases and the low-noise amplifier may be saturated. There was a problem.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a receiving circuit capable of removing an interference wave even when the frequency of the interference wave fluctuates with time. To do.

  In the receiving circuit according to the present invention, a frequency different from the frequency of the transmission signal included in the radio signal is set in the pass band, and among the signals included in the radio signal, the signal in the pass band is selected. A band-pass filter that passes through and a frequency detection circuit that detects the frequency of the interference wave included in the signal that has passed through the band-pass filter are provided, and the frequency of the interference wave detected by the frequency detection circuit is set as the cutoff band. The variable cutoff filter is adapted to block the interference wave included in the radio signal.

  According to the present invention, a frequency different from the frequency of the transmission signal included in the radio signal is set in the passband, and among the signals included in the radio signal, the signal in the passband is passed. A variable that has a bandpass filter and a frequency detection circuit that detects the frequency of the jamming wave included in the signal that has passed through the bandpass filter, and the frequency of the jamming wave detected by the frequency detection circuit is set to the cutoff band Since the type cutoff filter is configured to block the interference wave included in the radio signal, even when the frequency of the interference wave fluctuates with the passage of time, the effect of removing the interference wave can be obtained. is there.

It is a block diagram which shows the receiver circuit by Embodiment 1 of this invention. It is explanatory drawing which shows the frequency of the transmission signal and interference wave which are contained in the radio signal received with the antenna. It is explanatory drawing which shows the spectrum of the radio signal at the time of receiving time t0, and the pass band of each filter mounted in the receiving circuit of FIG. It is explanatory drawing which shows the spectrum of the radio signal at the time of reception t1, and the pass band of each filter mounted in the receiving circuit of FIG. It is explanatory drawing which shows the spectrum of the signal which passed the band pass filter. It is a block diagram which shows the receiver circuit by Embodiment 2 of this invention. It is explanatory drawing which shows the frequency of the transmission signal contained in the radio signal received with the antenna 1, and the interference waves a and b. It is explanatory drawing which shows the spectrum of the radio signal at the time of receiving time t0, and the pass band of each filter mounted in the receiving circuit of FIG. It is explanatory drawing which shows the spectrum of the radio signal at the reception time t1, and the pass band of each filter mounted in the receiving circuit of FIG. It is explanatory drawing which shows the spectrum of the radio signal at the time of reception t2, and the pass band of each filter mounted in the receiving circuit of FIG.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a receiving circuit according to Embodiment 1 of the present invention, and FIG. 2 is an explanatory diagram showing frequencies of transmission signals and interference waves included in a radio signal received by an antenna 1.
3 is an explanatory diagram showing the spectrum of the radio signal at the reception time t0 and the passband of each filter mounted on the reception circuit in FIG. 1, and FIG. 4 is a diagram of the radio signal at the reception time t1. It is explanatory drawing which shows the pass band of a spectrum and each filter mounted in the receiving circuit of FIG.

In FIG. 1, an antenna 1 receives a radio signal including a transmission signal having a center frequency of fc and sideband frequencies of fc1 to fc2. However, it is assumed that an interference wave whose frequency fluctuates in the range of fnh0 to fnh1 with the passage of time is mixed in this radio signal.
In the example of FIG. 2, the center frequency of the disturbing wave at time t0 is fnh1, and the center frequency of the disturbing wave at time t1 is fnh0.

The bandpass filter 2 has a frequency higher than the center frequency fc of the transmission signal set in the passband A (fbpa1 to fbpa2), and has a frequency higher than the center frequency fc of the transmission signal among signals included in the radio signal. It is a band pass filter that passes a signal (pass band A signal).
The frequency detection circuit 3 has a reception spectrum (interference wave of interference wave) higher than a preset specific power P1 (power higher than the power of the side wave component of the transmission signal) in the reception spectrum of the signal that has passed through the bandpass filter 2. The control voltage v_fnh indicating the center frequency fnh of the reception spectrum is output to the variable band rejection filter 4.

In the variable band rejection filter 4, the frequency band including the center frequency fnh indicated by the control voltage v_fnh output from the frequency detection circuit 3 is set to the cut-off band B (for example, fbra 1 to fbra 2 or fbra 3 to fbra 4). Is a variable cutoff filter that blocks a jamming wave included in the signal and passes a signal other than the jamming wave (a signal in a band B ′ other than the cutoff band B).
The band pass filter 5 has a frequency band including the center frequency fc of the transmission signal and the sideband frequencies fc1 to fc2 set to a pass band C (fbpm1 to fbpm2), and the signal that has passed through the variable band rejection filter 4 It is the 2nd bandpass filter which lets the contained transmission signal pass.
The low noise amplifier 6 amplifies the power of the transmission signal that has passed through the band pass filter 5.

Next, the operation will be described.
The center frequency fc of the transmission signal is constant over time, but the center frequency fnh of the disturbing wave varies with time.
Hereinafter, an operation when the reception time of the radio signal at the antenna 1 is t0 and an operation when the reception time of the radio signal is t1 will be described.

First, the operation when the reception time of the radio signal at the antenna 1 is t0 will be described.
At the reception time t0, a radio signal including a transmission signal having the center frequency fc and an interference wave having the center frequency fnh1 is received by the antenna 1.
Since the bandpass filter 2 has a frequency higher than the center frequency fc of the transmission signal set in the passband A (fbpa1 to fbpa2), when the radio signal including the transmission signal and the interference wave is output from the antenna 1, Of the signals included in the signal, only signals having a frequency higher than the center frequency fc of the transmission signal (pass band A signals) are allowed to pass.

Accordingly, since the center frequency fc of the transmission signal and the sideband frequency fc1 of the transmission signal lower than the center frequency fc are lower than the passband A (fbpa1 to fbpa2) of the bandpass filter 2, the center of the transmission signal The component of the frequency fc and the side wave component of the transmission signal lower than the center frequency fc are blocked by the band pass filter 2.
On the other hand, the sideband frequency fc2 of the transmission signal higher than the center frequency fc and the center frequency fnh1 of the interference wave are included in the passband A (fbpa1 to fbpa2) of the bandpass filter 2 (fbpa1 < fc2 <fnh1 <fbpa2), the side wave component and the interference wave of the transmission signal higher than the center frequency fc pass through the band pass filter 2.

When a signal that has passed through the bandpass filter 2 (a sideband component or an interference wave of a transmission signal that is higher than the center frequency fc) is input to the frequency detection circuit 3, the received frequency of the signal that has passed through the bandpass filter 2 Among them, the reception spectrum of power higher than the preset specific power P1 is detected.
In the example of FIG. 3, the reception spectrum of the power higher than the specific power P1 is only the reception spectrum of the interference wave, and thus the reception spectrum of the interference wave is detected.
When detecting the reception spectrum of the interference wave, the frequency detection circuit 3 outputs a control voltage v_fnh1 indicating the center frequency fnh1 of the reception spectrum to the variable band rejection filter 4.

When the variable band rejection filter 4 receives the control voltage v_fnh1 from the frequency detection circuit 3, the frequency band including the center frequency fnh1 indicated by the control voltage v_fnh1 is set to the cutoff band B (fbra1 to fbra2).
When a wireless signal including a transmission signal and an interference wave is output from the antenna 1, the variable band rejection filter 4 blocks the interference wave of the center frequency fnh 1 included in the wireless signal, and signals other than the interference wave (A signal in a band B ′ other than the cutoff band B) is allowed to pass.
Therefore, the interference wave having the center frequency fnh1 is blocked by the variable band rejection filter 4, but the transmission signal passes through the variable band rejection filter 4.

The band pass filter 5 has passed through the variable band rejection filter 4 because the frequency band including the center frequency fc of the transmission signal and the sideband frequencies fc1 to fc2 is set to the pass band C (fbpm1 to fbpm2). When the signal is input, the transmission signal included in the signal that has passed through the variable band rejection filter 4 is passed.
That is, since the center frequency fc and the sideband frequencies fc1 to fc2 of the transmission signal are included in the pass band C (fbpm1 to fbpm2) of the bandpass filter 5 (fbpm1 <fc1 <fc <fc2 <fbpm2), transmission The component of the center frequency fc and the components of the sideband frequencies fc1 to fc2 pass through the bandpass filter 5.

  The low noise amplifier 6 amplifies the power of the signal that has passed through the band pass filter 5. The power of the signal amplified by the low noise amplifier 6 is an integral value in the pass band C of the band pass filter 5, but does not include an interference wave and is only a component of the transmission signal. Never saturates.

Next, the operation when the reception time of the radio signal at the antenna 1 is t1 will be described.
At reception time t1, a radio signal including a transmission signal having a center frequency fc and an interference wave having a center frequency fnh0 is received by the antenna 1.
Since the bandpass filter 2 has a frequency higher than the center frequency fc of the transmission signal set in the passband A (fbpa1 to fbpa2), when the radio signal including the transmission signal and the interference wave is output from the antenna 1, Of the signals included in the signal, only signals having a frequency higher than the center frequency fc of the transmission signal (pass band A signals) are allowed to pass.

Accordingly, since the center frequency fc of the transmission signal and the sideband frequency fc1 of the transmission signal lower than the center frequency fc are lower than the passband A (fbpa1 to fbpa2) of the bandpass filter 2, the center of the transmission signal The component of the frequency fc and the side wave component of the transmission signal lower than the center frequency fc are blocked by the band pass filter 2.
On the other hand, the sideband frequency fc2 of the transmission signal higher than the center frequency fc and the center frequency fnh0 of the interference wave are included in the passband A (fbpa1 to fbpa2) of the bandpass filter 2 (fbpa1 < fnh0 <fc2 <fbpa2), the side wave component and the interference wave of the transmission signal higher than the center frequency fc pass through the band pass filter 2.

When a signal that has passed through the bandpass filter 2 (a sideband component or an interference wave of a transmission signal that is higher than the center frequency fc) is input to the frequency detection circuit 3, the received frequency of the signal that has passed through the bandpass filter 2 Among them, the reception spectrum of power higher than the preset specific power P1 is detected.
In the example of FIG. 4, the reception spectrum of the power higher than the specific power P1 is only the reception spectrum of the interference wave, and thus the reception spectrum of the interference wave is detected.
When detecting the reception spectrum of the interference wave, the frequency detection circuit 3 outputs a control voltage v_fnh0 indicating the center frequency fnh0 of the reception spectrum to the variable band rejection filter 4.

When the variable band rejection filter 4 receives the control voltage v_fnh0 from the frequency detection circuit 3, the frequency band including the center frequency fnh0 indicated by the control voltage v_fnh0 is set to the cutoff band B (fbra3 to fbra4).
When the variable band rejection filter 4 outputs a radio signal including a transmission signal and an interfering wave from the antenna 1, the variable band rejection filter 4 blocks the interfering wave having the center frequency fnh0 included in the radio signal, and outputs a signal other than the interfering wave. (A signal in a band B ′ other than the cutoff band B) is allowed to pass.
Therefore, the interference wave having the center frequency fnh0 is blocked by the variable band rejection filter 4, but the transmission signal passes through the variable band rejection filter 4.
Since the interference wave having the center frequency fnh0 partially overlaps the side wave component of the transmission signal higher than the center frequency fc, the side wave component of the transmission signal in the portion overlapping the interference wave is also blocked. The

The band pass filter 5 has passed through the variable band rejection filter 4 because the frequency band including the center frequency fc of the transmission signal and the sideband frequencies fc1 to fc2 is set to the pass band C (fbpm1 to fbpm2). When the signal is input, the transmission signal included in the signal that has passed through the variable band rejection filter 4 is passed.
That is, since the center frequency fc and the sideband frequencies fc1 to fc2 of the transmission signal are included in the pass band C (fbpm1 to fbpm2) of the bandpass filter 5 (fbpm1 <fc1 <fc <fc2 <fbpm2), transmission The component of the center frequency fc and the components of the sideband frequencies fc1 to fc2 pass through the bandpass filter 5.

FIG. 5 is an explanatory diagram showing a spectrum of a signal that has passed through the bandpass filter 5.
The interference wave having the center frequency fnh0 partially overlaps the side wave component of the transmission signal higher than the center frequency fc, and the side wave component of the transmission signal overlapping the interference wave is a variable band rejection filter. 4, the spectrum of the signal that has passed through the bandpass filter 5 is as shown in FIG.

  The low noise amplifier 6 amplifies the power of the signal that has passed through the band pass filter 5. The power of the signal amplified by the low noise amplifier 6 is an integral value in the pass band C of the band pass filter 5, but does not include an interference wave and is only a component of the transmission signal. Never saturates.

  As is apparent from the above, according to the first embodiment, among the reception spectrum of the signal that has passed through the bandpass filter 2, the reception spectrum of the power higher than the preset specific power P1 (the reception spectrum of the interference wave) ) And outputs a control voltage v_fnh indicating the center frequency fnh of the reception spectrum to the variable band rejection filter 4, and the center frequency indicated by the control voltage v_fnh output from the frequency detection circuit 3 is provided. The variable band rejection filter 4 in which the frequency band including fnh is set to the cutoff band B cuts off the interference wave of the center frequency fnh included in the radio signal output from the antenna 1, Since the signal (the signal in the band B ′ other than the cutoff band B) is passed, the center frequency fnh of the interference wave Even if that varies with time, it will be able to remove the interference wave, as a result, an effect that can avoid saturation of the low noise amplifier 6 by power.

In the first embodiment, the receiving circuit that removes the interference wave whose center frequency fnh is higher than the center frequency fc of the transmission signal is shown. However, the interference wave whose center frequency fnh is lower than the center frequency fc of the transmission signal is removed. May be.
In this case, a frequency lower than the center frequency fc of the transmission signal is set in the pass band A (fbpa1 to fbpa2) of the bandpass filter 2 and is lower than the center frequency fc of the transmission signal among signals included in the radio signal. What is necessary is just to make it pass the signal of a frequency through the band pass filter 2.

  In the first embodiment, the reception circuit that removes the interference wave whose center frequency fnh varies with the passage of time has been described. However, the interference wave whose center frequency fnh does not vary with the passage of time is similarly removed. can do.

Embodiment 2. FIG.
In the first embodiment, the reception circuit that removes one interference wave mixed in the radio signal is shown. However, in the second embodiment, the two interference waves a and b mixed in the radio signal are displayed. The receiving circuit to be removed will be described.

FIG. 6 is a block diagram showing a receiving circuit according to the second embodiment of the present invention. In the figure, the same reference numerals as those in FIG.
However, in the second embodiment, the bandpass filter 2 is used as a first bandpass filter, the frequency detection circuit 3 is used as a first frequency detection circuit, and the variable band rejection filter 4 is a first bandpass filter. It is used as a variable cutoff filter, and the band pass filter 5 is used as a third band pass filter.
The frequency detection circuit 3 detects the reception spectrum of the interference wave a, and outputs a control voltage v_fnh indicating the center frequency fnh of the reception spectrum to the variable band rejection filter 4. It is assumed that the interference wave a included in the radio signal is blocked.

FIG. 7 is an explanatory diagram showing the frequencies of transmission signals and interference waves a and b included in a radio signal received by the antenna 1.
8 is an explanatory diagram showing the spectrum of the radio signal at the reception time t0 and the passband of each filter mounted in the reception circuit of FIG. 6, and FIG. 9 is the radio signal at the reception time t1. FIG. 10 is an explanatory diagram showing a spectrum and a pass band of each filter mounted on the receiving circuit of FIG. 6, and FIG. 10 shows a spectrum of a radio signal at the reception time t2 and each filter mounted on the receiving circuit of FIG. It is explanatory drawing which shows the pass band of.

In FIG. 6, the bandpass filter 11 has a frequency lower than the center frequency fc of the transmission signal set in the passband D (fbpb1 to fbpb2), and the center frequency fc of the transmission signal among the signals included in the radio signal. This is a second bandpass filter that passes a signal having a lower frequency (passband D signal).
The frequency detection circuit 12 has a reception spectrum (interfering wave b) higher than a preset specific power P1 (power higher than the power of the side wave component of the transmission signal) in the reception spectrum of the signal that has passed through the bandpass filter 11. And a control voltage v_fnl indicating the center frequency fnl of the received spectrum is output to the variable band rejection filter 13.

  In the variable band rejection filter 13, the frequency band including the center frequency fnl indicated by the control voltage v_fnl output from the frequency detection circuit 12 is set to the cutoff band E (for example, fbrb 1 to fbrb 2, fbrb 3 to fbrb 4). Is a second variable cutoff filter that allows signals other than the interference wave included in the signal (a signal in a band E ′ other than the cutoff band E) to pass therethrough.

Next, the operation will be described.
The center frequency fc of the transmission signal is constant over time, but the center frequencies fnh and fnl of the interference waves a and b vary with time.
Hereinafter, an operation when the reception time of the radio signal at the antenna 1 is t0, an operation when the reception time of the radio signal is t1, and an operation when the reception time of the radio signal is t2 will be described.

First, the operation when the reception time of the radio signal at the antenna 1 is t0 will be described.
At the reception time t0, a radio signal including a transmission signal having a center frequency fc and an interference wave a having a center frequency fnh1 is received by the antenna 1.
In the example of FIG. 7, the interference wave b is not mixed in the radio signal at the reception time t0.
Since the bandpass filter 2 has a frequency higher than the center frequency fc of the transmission signal set in the passband A (fbpa1 to fbpa2), when a radio signal including the transmission signal and the interference wave a is output from the antenna 1, Of the signals included in the radio signal, only signals having a frequency higher than the center frequency fc of the transmission signal (pass band A signals) are allowed to pass.

Accordingly, since the center frequency fc of the transmission signal and the sideband frequency fc1 of the transmission signal lower than the center frequency fc are lower than the passband A (fbpa1 to fbpa2) of the bandpass filter 2, the center of the transmission signal The component of the frequency fc and the side wave component of the transmission signal lower than the center frequency fc are blocked by the band pass filter 2.
On the other hand, the sideband frequency fc2 of the transmission signal higher than the center frequency fc and the center frequency fnh1 of the interference wave a are included in the passband A (fbpa1 to fbpa2) of the bandpass filter 2 (fbpa1). <Fc2 <fnh1 <fbpa2), the side wave component of the transmission signal transmission signal on the side higher than the center frequency fc and the interference wave a pass through the band-pass filter 2.

When a signal that has passed through the bandpass filter 2 (a sideband component of the transmission signal that is higher than the center frequency fc, an interference wave a) is input to the frequency detection circuit 3, the received spectrum of the signal that has passed through the bandpass filter 2 Among them, a reception spectrum having a power higher than the preset specific power P1 is detected.
In the example of FIG. 8, since the reception spectrum of power higher than the specific power P1 is only the reception spectrum of the interference wave a, the reception spectrum of the interference wave a is detected.
When detecting the reception spectrum of the interference wave a, the frequency detection circuit 3 outputs a control voltage v_fnh1 indicating the center frequency fnh1 of the reception spectrum to the variable band rejection filter 4.

When the variable band rejection filter 4 receives the control voltage v_fnh1 from the frequency detection circuit 3, the frequency band including the center frequency fnh1 indicated by the control voltage v_fnh1 is set to the cutoff band B (fbra1 to fbra2).
When the wireless signal including the transmission signal and the interference wave a is output from the antenna 1, the variable band rejection filter 4 blocks the interference wave a having the center frequency fnh 1 included in the wireless signal, and the interference wave a Other signals (signals in the band B ′ other than the cutoff band B) are passed.
Therefore, the interference wave a having the center frequency fnh1 is blocked by the variable band rejection filter 4, but the transmission signal passes through the variable band rejection filter 4.

Since the bandpass filter 11 has a frequency lower than the center frequency fc of the transmission signal set in the passband D (fbpb1 to fbpb2), when a radio signal including the transmission signal and the interference wave a is output from the antenna 1, Of the signals included in the radio signal, only a signal having a frequency lower than the center frequency fc of the transmission signal (a signal in the pass band D) is allowed to pass.
Therefore, the center frequency fc of the transmission signal and the sideband frequency fc2 of the transmission signal higher than the center frequency fc are higher than the passband D (fbpb1 to fbpb2) of the bandpass filter 11, and therefore the center of the transmission signal The component of the frequency fc and the side wave component of the transmission signal higher than the center frequency fc are blocked by the band pass filter 11.
On the other hand, since the sideband frequency fc1 of the transmission signal lower than the center frequency fc is included in the passband D (fbpb1 to fbpb2) of the bandpass filter 11 (fbpb1 <fc1 <fbpb2), the center frequency fc The side wave component of the lower transmission signal passes through the bandpass filter 11.

When a signal that has passed through the bandpass filter 11 (a sideband component of a transmission signal that is lower than the center frequency fc) is input to the frequency detection circuit 12, in the reception spectrum of the signal that has passed through the bandpass filter 11 A reception spectrum having a power higher than a predetermined specific power P1 is detected.
In the example of FIG. 8, since there is no reception spectrum of power higher than the specific power P <b> 1 (no interference wave b), the control voltage v_fnl is not output to the variable band rejection filter 13.

Since the variable band rejection filter 13 does not receive the control voltage v_fnl from the frequency detection circuit 12, the cutoff band E (fbrb to fbrb) is not set.
Therefore, the signal that has passed through the variable band rejection filter 4 passes through the variable band rejection filter 13.

The band pass filter 5 has passed through the variable band rejection filter 13 because the frequency band including the center frequency fc of the transmission signal and the sideband frequencies fc1 to fc2 is set to the pass band C (fbpm1 to fbpm2). When the signal is input, the transmission signal included in the signal that has passed through the variable band rejection filter 13 is passed.
That is, since the center frequency fc and the sideband frequencies fc1 to fc2 of the transmission signal are included in the pass band C (fbpm1 to fbpm2) of the bandpass filter 5 (fbpm1 <fc1 <fc <fc2 <fbpm2), transmission The component of the center frequency fc and the components of the sideband frequencies fc1 to fc2 pass through the bandpass filter 5.

  The low noise amplifier 6 amplifies the power of the signal that has passed through the band pass filter 5. The power of the signal amplified by the low noise amplifier 6 is an integral value in the pass band C of the band pass filter 5, but does not include an interference wave and is only a component of the transmission signal. Never saturates.

Next, the operation when the reception time of the radio signal at the antenna 1 is t1 will be described.
At the reception time t1, a radio signal including a transmission signal having a center frequency fc, an interference wave a having a center frequency fnh0, and an interference wave b having a center frequency fnl0 is received by the antenna 1.
Since the bandpass filter 2 has a frequency higher than the center frequency fc of the transmission signal set in the passband A (fbpa1 to fbpa2), a radio signal including the transmission signal and the interference waves a and b is output from the antenna 1. Then, only a signal having a frequency higher than the center frequency fc of the transmission signal (a signal in the pass band A) among the signals included in the radio signal is allowed to pass.

Therefore, for the center frequency fc of the transmission signal, the sideband frequency fc1 of the transmission signal lower than the center frequency fc, and the center frequency fnl0 of the interference wave b, the passband A (fbpa1 to fbpa2) of the bandpass filter 2 is used. ), The component of the transmission signal center frequency fc, the side signal component of the transmission signal lower than the center frequency fc, and the interference wave b are blocked by the bandpass filter 2.
On the other hand, the sideband frequency fc2 of the transmission signal higher than the center frequency fc and the center frequency fnh0 of the interference wave a are included in the passband A (fbpa1 to fbpa2) of the bandpass filter 2 (fbpa1). <Fnh0 <fc2 <fbpa2), the side wave component of the transmission signal higher than the center frequency fc and the interference wave a pass through the bandpass filter 2.

When a signal that has passed through the bandpass filter 2 (a sideband component of the transmission signal that is higher than the center frequency fc, an interference wave a) is input to the frequency detection circuit 3, the received spectrum of the signal that has passed through the bandpass filter 2 Among them, a reception spectrum having a power higher than the preset specific power P1 is detected.
In the example of FIG. 9, the reception spectrum of power higher than the specific power P1 is only the reception spectrum of the interference wave a, and therefore the reception spectrum of the interference wave a is detected.
When the frequency detection circuit 3 detects the reception spectrum of the interference wave a, the frequency detection circuit 3 outputs a control voltage v_fnh0 indicating the center frequency fnh0 of the reception spectrum to the variable band rejection filter 4.

When the variable band rejection filter 4 receives the control voltage v_fnh0 from the frequency detection circuit 3, the frequency band including the center frequency fnh0 indicated by the control voltage v_fnh0 is set to the cutoff band B (fbra3 to fbra4).
When the radio signal including the transmission signal and the interference waves a and b is output from the antenna 1, the variable band rejection filter 4 blocks the interference wave a having the center frequency fnh 0 included in the radio signal. A signal other than the wave a (a signal in a band B ′ other than the cutoff band B) is passed.
Therefore, the interference wave a having the center frequency fnh0 is blocked by the variable band rejection filter 4, but the transmission signal and the interference wave b pass through the variable band rejection filter 4.

Since the bandpass filter 11 has a frequency lower than the center frequency fc of the transmission signal set in the passband D (fbpb1 to fbpb2), a radio signal including the transmission signal and the interference waves a and b is output from the antenna 1. Then, among the signals included in the radio signal, only a signal having a frequency lower than the center frequency fc of the transmission signal (a signal in the pass band D) is allowed to pass.
Therefore, with respect to the center frequency fc of the transmission signal, the sideband frequency fc2 of the transmission signal higher than the center frequency fc, and the center frequency fnh0 of the interference wave a, the passband D (fbpb1 to fbpb2) of the bandpass filter 11 is used. ), The component of the transmission signal center frequency fc, the side signal component of the transmission signal higher than the center frequency fc, and the interference wave a are blocked by the bandpass filter 11.
On the other hand, the sideband frequency fc1 of the transmission signal lower than the center frequency fc and the center frequency fn10 of the interference wave b are included in the passband D (fbpb1 to fbpb2) of the bandpass filter 11 (fbpb1). <Fnl0 <fc1 <fbpb2), the side wave component of the transmission signal on the side lower than the center frequency fc and the interference wave b pass through the band pass filter 11.

When the signal that has passed through the bandpass filter 11 (the sideband component of the transmission signal lower than the center frequency fc, the interference wave b) is input to the frequency detection circuit 12, the reception spectrum of the signal that has passed through the bandpass filter 11 Among them, a reception spectrum having a power higher than the preset specific power P1 is detected.
In the example of FIG. 9, since the reception spectrum of power higher than the specific power P1 is only the reception spectrum of the interference wave b, the reception spectrum of the interference wave b is detected.
When detecting the reception spectrum of the interference wave b, the frequency detection circuit 12 outputs a control voltage v_fnl0 indicating the center frequency fnl0 of the reception spectrum to the variable band rejection filter 13.

When the variable band rejection filter 13 receives the control voltage v_fnl0 from the frequency detection circuit 12, the frequency band including the center frequency fnl0 indicated by the control voltage v_fnl0 is set to the cutoff band E (fbrb1 to fbrb2).
The variable band rejection filter 13 cuts off the interference wave b having the center frequency fnl0 from the signals (transmission signal, interference wave b) that have passed through the variable band rejection filter 4, and signals other than the interference wave b ( A signal in a band E ′ other than the cutoff band E) is allowed to pass.
Therefore, the interference wave b having the center frequency fnl1 is blocked by the variable band rejection filter 13, but the transmission signal passes through the variable band rejection filter 13.

The band pass filter 5 has passed through the variable band rejection filter 13 because the frequency band including the center frequency fc of the transmission signal and the sideband frequencies fc1 to fc2 is set to the pass band C (fbpm1 to fbpm2). When the signal is input, the transmission signal included in the signal that has passed through the variable band rejection filter 13 is passed.
That is, since the center frequency fc and the sideband frequencies fc1 to fc2 of the transmission signal are included in the pass band C (fbpm1 to fbpm2) of the bandpass filter 5 (fbpm1 <fc1 <fc <fc2 <fbpm2), transmission The component of the center frequency fc and the components of the sideband frequencies fc1 to fc2 pass through the bandpass filter 5.

  The low noise amplifier 6 amplifies the power of the signal that has passed through the band pass filter 5. The power of the signal amplified by the low noise amplifier 6 is an integral value in the pass band C of the band pass filter 5, but does not include an interference wave and is only a component of the transmission signal. Never saturates.

Next, the operation when the reception time of the radio signal at the antenna 1 is t2 will be described.
At the reception time t2, the antenna 1 receives a radio signal including the transmission signal having the center frequency fc, the interference wave a having the center frequency fnh01, and the interference wave b having the center frequency fnl1.
Since the bandpass filter 2 has a frequency higher than the center frequency fc of the transmission signal set in the passband A (fbpa1 to fbpa2), a radio signal including the transmission signal and the interference waves a and b is output from the antenna 1. Then, only a signal having a frequency higher than the center frequency fc of the transmission signal (a signal in the pass band A) among the signals included in the radio signal is allowed to pass.

Therefore, for the center frequency fc of the transmission signal, the sideband frequency fc1 of the transmission signal lower than the center frequency fc, and the center frequency fnl1 of the interference wave b, the passband A (fbpa1 to fbpa2) of the bandpass filter 2 is used. ), The component of the transmission signal center frequency fc, the side signal component of the transmission signal lower than the center frequency fc, and the interference wave b are blocked by the bandpass filter 2.
On the other hand, the sideband frequency fc2 of the transmission signal higher than the center frequency fc and the center frequency fnh01 of the interference wave a are included in the passband A (fbpa1 to fbpa2) of the bandpass filter 2 (fbpa1). <Fnh01 <fc2 <fbpa2), the side wave component of the transmission signal higher than the center frequency fc and the interference wave a pass through the band-pass filter 2.

When a signal that has passed through the bandpass filter 2 (a sideband component of the transmission signal that is higher than the center frequency fc, an interference wave a) is input to the frequency detection circuit 3, the received spectrum of the signal that has passed through the bandpass filter 2 Among them, a reception spectrum having a power higher than the preset specific power P1 is detected.
In the example of FIG. 10, since the reception spectrum of power higher than the specific power P1 is only the reception spectrum of the interference wave a, the reception spectrum of the interference wave a is detected.
When the frequency detection circuit 3 detects the reception spectrum of the interference wave a, it outputs a control voltage v_fnh01 indicating the center frequency fnh01 of the reception spectrum to the variable band rejection filter 4.

When the variable band rejection filter 4 receives the control voltage v_fnh01 from the frequency detection circuit 3, the frequency band including the center frequency fnh01 indicated by the control voltage v_fnh01 is set to the cutoff band B (fbra5 to fbra6).
When the wireless signal including the transmission signal and the interference waves a and b is output from the antenna 1, the variable band rejection filter 4 blocks the interference wave a having the center frequency fnh01 included in the radio signal and performs interference. A signal other than the wave a (a signal in a band B ′ other than the cutoff band B) is passed.
Therefore, the interference wave a having the center frequency fnh01 is blocked by the variable band rejection filter 4, but the transmission signal and the interference wave b pass through the variable band rejection filter 4.

Since the bandpass filter 11 has a frequency lower than the center frequency fc of the transmission signal set in the passband D (fbpb1 to fbpb2), a radio signal including the transmission signal and the interference waves a and b is output from the antenna 1. Then, among the signals included in the radio signal, only a signal having a frequency lower than the center frequency fc of the transmission signal (a signal in the pass band D) is allowed to pass.
Therefore, for the center frequency fc of the transmission signal, the sideband frequency fc2 of the transmission signal higher than the center frequency fc, and the center frequency fnh01 of the interference wave a, the passband D (fbpb1 to fbpb2) of the bandpass filter 11 is used. ), The component of the transmission signal center frequency fc, the side signal component of the transmission signal higher than the center frequency fc, and the interference wave a are blocked by the bandpass filter 11.
On the other hand, the sideband frequency fc1 of the transmission signal lower than the center frequency fc and the center frequency fnl1 of the interference wave b are included in the passband D (fbpb1 to fbpb2) of the bandpass filter 11 (fbpb1). <Fc1 <fnl1 <fbpb2), the side wave component of the transmission signal on the side lower than the center frequency fc and the interference wave b pass through the band pass filter 11.

When the signal that has passed through the bandpass filter 11 (the sideband component of the transmission signal lower than the center frequency fc, the interference wave b) is input to the frequency detection circuit 12, the reception spectrum of the signal that has passed through the bandpass filter 11 Among them, a reception spectrum having a power higher than the preset specific power P1 is detected.
In the example of FIG. 10, since the reception spectrum of power higher than the specific power P1 is only the reception spectrum of the interference wave b, the reception spectrum of the interference wave b is detected.
When detecting the reception spectrum of the interference wave b, the frequency detection circuit 12 outputs a control voltage v_fnl1 indicating the center frequency fnl1 of the reception spectrum to the variable band rejection filter 13.

When the variable band rejection filter 13 receives the control voltage v_fnl1 from the frequency detection circuit 12, the frequency band including the center frequency fnl1 indicated by the control voltage v_fnl1 is set to the cutoff band E (fbrb3 to fbrb4).
The variable band rejection filter 13 blocks the interference wave b having the center frequency fnl1 from the signals (transmission signal, interference wave b) that have passed through the variable band rejection filter 4, and signals other than the interference wave b ( A signal in a band E ′ other than the cutoff band E) is allowed to pass.
Therefore, the interference wave b having the center frequency fnl1 is blocked by the variable band rejection filter 13, but the transmission signal passes through the variable band rejection filter 13.

The band pass filter 5 has passed through the variable band rejection filter 13 because the frequency band including the center frequency fc of the transmission signal and the sideband frequencies fc1 to fc2 is set to the pass band C (fbpm1 to fbpm2). When the signal is input, the transmission signal included in the signal that has passed through the variable band rejection filter 13 is passed.
That is, since the center frequency fc and the sideband frequencies fc1 to fc2 of the transmission signal are included in the pass band C (fbpm1 to fbpm2) of the bandpass filter 5 (fbpm1 <fc1 <fc <fc2 <fbpm2), transmission The component of the center frequency fc and the components of the sideband frequencies fc1 to fc2 pass through the bandpass filter 5.

  The low noise amplifier 6 amplifies the power of the signal that has passed through the band pass filter 5. The power of the signal amplified by the low noise amplifier 6 is an integral value in the pass band C of the band pass filter 5, but does not include an interference wave and is only a component of the transmission signal. Never saturates.

  As is apparent from the above, according to the second embodiment, the reception spectrum of the power higher than the predetermined specific power P1 (reception of the interference wave b) in the reception spectrum of the signal that has passed through the bandpass filter 11 is obtained. A frequency detection circuit 12 for detecting a spectrum) and outputting a control voltage v_fnl indicating the center frequency fnl of the received spectrum to the variable band rejection filter 13 is provided, and the center indicated by the control voltage v_fnl output from the frequency detection circuit 12 The variable band rejection filter 13 in which the frequency band including the frequency fnl is set as the cutoff band E cuts off the interference wave b included in the radio signal, and signals other than the interference wave b (other than the cutoff band E) Band E ′), the center frequencies fnh and fnl of the two disturbing waves a and b are time Even if that varies with the passage, it will be able to remove the interference wave a, b, as a result, an effect that can avoid saturation of the low noise amplifier 6 by power.

  In the second embodiment, the receiving circuit that removes the interference waves a and b whose center frequencies fnh and fnl fluctuate with time has been described. However, the center frequencies fnh and fnl do not fluctuate with time. The interference waves a and b can be similarly removed.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  1 antenna, 2 bandpass filter (bandpass filter, first bandpass filter), 3 frequency detection circuit (first frequency detection circuit), 4 variable band rejection filter (variable cutoff filter, first variable) Type cutoff filter), 5 bandpass filter (second bandpass filter, third bandpass filter), 6 low noise amplifier, 11 bandpass filter (second bandpass filter), 12 frequency detection circuit (second Frequency detecting circuit), 13 variable band rejection filter (second variable cutoff filter).

Claims (6)

A frequency different from the frequency of the transmission signal included in the radio signal is set in the passband, and among the signals included in the radio signal, a bandpass filter that passes a signal in the passband;
A frequency detection circuit that detects a frequency of an interfering wave included in the signal that has passed through the bandpass filter;
A receiving circuit comprising: a variable cutoff filter configured to cut off a jamming wave included in the radio signal, wherein a frequency of the jamming wave detected by the frequency detection circuit is set in a cutoff band.   The band pass filter has a frequency higher than the frequency of the transmission signal included in the radio signal set as a pass band, and among the signals included in the radio signal, the frequency higher than the frequency of the transmission signal. The receiving circuit according to claim 1, wherein the signal is passed.   The bandpass filter has a frequency lower than the frequency of the transmission signal included in the radio signal set as a passband, and the frequency included in the radio signal is lower than the frequency of the transmission signal. The receiving circuit according to claim 1, wherein the signal is passed.   The frequency of the said transmission signal is set to the pass band, The 2nd band pass filter which passes the transmission signal contained in the signal which passed the said variable cutoff filter is provided. The receiving circuit according to claim 3. A frequency higher than the frequency of the transmission signal included in the wireless signal is set as a passband, and a first signal that passes a signal having a frequency higher than the frequency of the transmission signal among the signals included in the wireless signal. A bandpass filter,
A first frequency detection circuit for detecting a frequency of a first disturbance wave included in a signal that has passed through the first bandpass filter;
A first variable cutoff filter that sets a frequency of a first disturbance wave detected by the first frequency detection circuit to a cutoff band and blocks the first disturbance wave included in the radio signal;
A frequency lower than the frequency of the transmission signal included in the radio signal is set as a pass band, and among the signals included in the radio signal, a signal having a frequency lower than the frequency of the transmission signal is passed. Two bandpass filters;
A second frequency detection circuit for detecting a frequency of a second interference wave included in the signal that has passed through the second bandpass filter;
The frequency of the second interference wave detected by the second frequency detection circuit is set to a cutoff band, and the second interference wave included in the signal that has passed through the first variable cutoff filter is blocked. A receiving circuit comprising: a second variable cutoff filter.   A frequency band of the transmission signal is set to a pass band, and a third band pass filter that passes the transmission signal included in the signal that has passed through the second variable cutoff filter is provided. The receiving circuit according to claim 5.

Images