JP3735278B2 - Receiving machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a receiver.
[0002]
[Prior art]
There is known a device that can receive (demodulate) signals in different bands (frequency bands) included in a received signal by using a frequency conversion circuit so that the frequencies are aligned and received by a common receiving unit. For example, a receiver that receives a broadcast by DAB (Digital Audio Broadcasting), which is a method of digital audio broadcasting using a terrestrial broadcast wave or a satellite broadcast wave, which has been developed in recent years. In DAB, two frequency bands of Band (band) -III and L-Band are used. The frequency band of Band-III is 174 to 240 MHz, and the frequency band of L-Band is 1452 to 1492 MHz.
[0003]
FIG. 6 is a block diagram showing a configuration of a DAB receiver according to such a conventional example. This receiver receives signals in both frequency bands of L-Band and Band-III, but a low-frequency Band-III signal is supplied to the Band-III receiver 1 as it is, and a high frequency L- The Band-III receiving unit 1 is shared by converting the Band signal to the Band-III frequency and supplying it to the Band-III receiving unit 1. That is, an L-Band frequency converter 3 and a Band-III LPF (Low Pass Filter) 4 are provided in parallel between the antenna input terminal 2 and the switch SW, and the antenna input terminal 2 is passed through. An input reception signal from the antenna ANT is supplied to the Band-III reception unit 1 through the frequency conversion unit 3 or the LPF 4 according to the switching state of the switch SW.
[0004]
The frequency converter 3 includes a BPF (Band Pass Filter) 5 that extracts an L-Band signal from a received signal, an RF amplifier 6 that amplifies the output of the BPF 5, and an amplified L-Band signal that is Band-III. Of the RF amplifier 6 based on the output of the frequency converter (mixer) 7 for converting to the frequency of the frequency, the local oscillator (PLL: Phase Locked Loop) 8 for supplying a signal of a constant frequency to the frequency converter 7, and the output of the frequency converter 7. An AGC detector 9 for outputting an AGC (Automatic Gain Control) voltage for controlling the gain is provided. The output side of the LPF 4 is connected to one input terminal t1 of the switch SW, and the output side of the frequency converter 7 is connected to the other input terminal t2.
[0005]
The Band-III receiver 1 receives an output from the switch SW as an RF amplifier 10, a frequency converter 11 that converts the output of the RF amplifier 10 into an intermediate frequency (IF), and an output from the frequency converter 11. Based on the AGC detector 12 for supplying a gain control voltage (AGC voltage) to the RF amplification unit 10, the IF amplification unit 13 for amplifying the output of the frequency conversion unit 11, and the demodulation based on the signal from the IF amplification unit 13 The unit 14 is provided. The RF amplifying unit 10 includes a BPF 15, an RF amplifier 16, and a BPF 17 that amplify after limiting the output of the switch SW to a predetermined pass frequency band, and further limit the output to a predetermined pass frequency band. The frequency converter 11 includes a local oscillator (PLL) 18 that outputs a signal having a frequency corresponding to the reception frequency, and a frequency converter that converts the output of the BPF 17 into an intermediate frequency by mixing the signal from the local oscillator 18 with the local oscillator (PLL) 18. 19.
[0006]
Reference numeral 20 in the figure indicates switching of the switch SW, power on / off of the frequency conversion unit 3, pass frequency bands of the BPFs 15 and 17, so that the intended Band-III or L-Band can be received. This is a control unit that controls the oscillation frequency and the like of the local oscillator 18.
[0007]
In this configuration, when the L-Band is received, the switch SW is switched to the terminal t2 side. At this time, the received signal from the antenna ANT inputted to the frequency converter 3 via the antenna input terminal 2 is limited to the passing frequency band by the BPF 5, amplified by the RF amplifier 6, and the local oscillator 8 in the frequency converter 7. Is mixed with the signal from, and converted to a signal in the Band-III frequency band (174 to 240 MHz). The frequency-converted signal is input to the AGC detector 9 to generate a gain control voltage (AGC voltage) to the RF amplifier 6, and is also input to the Band-III receiver 1 through the switch SW and demodulated. The
[0008]
When receiving Band-III, the switch SW is switched to the terminal t1 side. At this time, the signal from the antenna ANT input to the antenna input terminal 2 is limited in the high frequency component by the LPF 4 and is input to the Band-III receiving unit 1 via the switch SW and demodulated. During this time, the frequency converter 3 is powered off by a control signal from the controller 20.
[0009]
The signal from the switch SW input to the Band-III receiver 1 is limited to the pass frequency band by the BPF 15, amplified by the RF amplifier 16, and further limited to the pass frequency band by the BPF 17, and then the frequency converter. 19 is input. The signal input to the frequency converter 19 is mixed with the signal from the local oscillator 18 and converted to an intermediate frequency. The signal converted to the intermediate frequency is supplied to the AGC detector 12, generates a gain control voltage (AGC voltage) to the RF amplifier 16, is amplified by the IF amplifier 13, and is demodulated by the demodulator 14.
[0010]
[Problems to be solved by the invention]
However, according to this conventional technique, a semiconductor switch, a relay, or the like is used as the switch SW, and the isolation of the switch SW is about 30 dB. Therefore, the switch SW is not tilted (not conductive) with respect to the terminal. However, a signal lower by about 30 dB than the signal passing through the switch SW (the signal on the conductive side) is output (leaks). Thus, when the switch SW is not sufficiently isolated and an L-Band having a high frequency is received, if the Band-III signal having a low frequency is a strong electric field, the strong electric field signal is disturbed. This causes a problem that demodulation cannot be performed. Note that a situation where an L-Band signal having a high frequency interferes with reception of a Band-III having a low frequency is also conceivable. In this case, measures such as cutting off the power supply of the frequency conversion unit 3 should be taken. There is no problem.
[0011]
Further, since the signal loss from the antenna input terminal 2 to the RF amplifier 16 affects the reception sensitivity of the Band-III, it is necessary to shorten the distance from the antenna input terminal 2 to the switch SW in order to reduce this loss. . For this reason, there also exists a problem that arrangement | positioning of the components of LPF4 and the frequency conversion part 3 is restrict | limited.
[0012]
An object of the present invention is to prevent the influence of a lower frequency band that may be received during reception of a higher frequency band in a receiver in view of the problems of the prior art. Another object is to improve the degree of freedom of component placement by eliminating the need to shorten the distance from the antenna input terminal to the switch.
[0013]
[Means for Solving the Problems]
In order to achieve this object, the receiver according to the first aspect of the invention is inputted with frequency conversion means for converting a signal in the first frequency band into a signal in the second frequency band having a lower frequency than the first frequency band. Switch means for selectively outputting and supplying either the second frequency band signal or the first frequency band signal subjected to the frequency conversion, and common for performing demodulation on each selectively supplied signal When demodulating the second frequency band signal in the receiver having the demodulation means, the second frequency band signal input to the switch means is allowed to pass and the frequency conversion is performed. When demodulating a signal in one frequency band, a filter for attenuating the signal intensity of the second frequency band input to the switch means is provided before the switch means. And wherein the door.
[0014]
Here, as a receiver, for example, a vehicle-mounted receiver that receives Band-III and L-Band broadcasting by DAB (Digital Audio Broadcasting) is applicable. In addition, the “signal in the first frequency band” may include only a signal in a part of the first frequency band. The same applies to signals in the second frequency band.
[0015]
In this configuration, when receiving the first frequency band, the signal of the first frequency band is converted to the frequency of the second frequency band and supplied to the demodulating means through the switch means. At that time, there is a possibility that the signal of the first frequency band that has been subjected to frequency conversion cannot be demodulated due to an adverse effect of the signal of the second frequency band input to the switch means. Is attenuated by the filter before the input to the switch means, so that the adverse effect is prevented. On the other hand, this filter passes the signal of the second frequency band when demodulating the signal of the second frequency band.
[0016]
A receiver according to a second invention is characterized in that, in the first invention, the receiver includes a low-pass filter having a variable cutoff frequency and a band-pass filter having a variable pass frequency band as the filter.
[0017]
A receiver according to a third invention is the receiver according to the second invention, wherein when the signal of the first frequency band subjected to the frequency conversion is demodulated, the cutoff frequency is set to be lower than the lower limit frequency of the second frequency band. The signal intensity of the second frequency band is attenuated by the filter by lowering and raising the lower limit of the frequency of the pass frequency band above the upper limit of the frequency of the second frequency band.
[0018]
A receiver according to a fourth invention is the receiver according to the first to third inventions, wherein when the signal of the second frequency band is demodulated, the signal strength of the second frequency band input to the switch means is changed to the switch. Amplifying means for amplifying before being input to the means, and when the demodulation is performed on the signal of the first frequency band subjected to the frequency conversion, the amplifying means is connected to the switch means by turning off the power. It is characterized by attenuating the input signal strength of the second frequency band.
[0019]
According to a fifth aspect of the present invention, the receiver according to the fourth aspect further comprises variable attenuation means for variably attenuating the signal intensity of the second frequency band input to the switch means before the switch means. The means adjusts the intensity of the signal in the second frequency band according to the intensity when the signal in the second frequency band is demodulated, and the signal in the first frequency band subjected to the frequency conversion. When demodulation is performed, the intensity of the signal in the second frequency band input to the switch means is attenuated by a predetermined attenuation amount.
[0020]
A receiver according to a sixth invention is the receiver according to the fifth invention, wherein the variable attenuating means adjusts the signal strength of the second frequency band to the amplifying means when demodulation is performed on the signal of the second frequency band. It is performed based on the control voltage.
[0021]
According to a seventh aspect of the present invention, there is provided a receiver for converting a signal of a first frequency band into a signal of a frequency of a second frequency band, an input signal of the second frequency band or the frequency conversion. In a receiver comprising: switch means for selectively outputting and supplying any one of the signals in the first frequency band made; and common demodulation means for demodulating each selectively supplied signal, Amplifying means for amplifying a signal in the second frequency band before input to the switch means is provided.
[0022]
Conventionally, it has been necessary to shorten the distance to the switch means to reduce the influence of signal loss on reception sensitivity. However, in the present invention, the signal strength in the second frequency band is amplified before being input to the switch means. In this way, it is possible to eliminate the necessity of shortening the distance to the switch means and to ensure the degree of freedom of component placement.
[0023]
The receiver according to an eighth invention is the receiver according to the seventh invention, wherein the amplifying means is connected to the switch means when power is turned off when the first frequency band subjected to the frequency conversion is demodulated. It is characterized by attenuating the input signal strength of the second frequency band.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block diagram showing a configuration of a receiver according to an embodiment of the present invention. This receiver includes an L-Band frequency conversion unit 3 and a Band-III RF amplification unit 21 and a switch SW which are provided in parallel between the antenna input terminal 2 connected to the antenna ANT and the switch SW. A receiving unit 22 that receives an output and a control unit 23 that controls each unit are provided. The output side of the frequency converter 3 is connected to the input terminal t2 of the switch SW, and the output side of the RF amplifier 21 is connected to the input terminal t1 of the switch SW. A reception signal from the antenna ANT input via the antenna input terminal 2 is supplied to the reception unit 22 via the frequency conversion unit 3 and supplied to the reception unit 22 via the Band-III RF amplification unit 21. Is switched by a switch SW. The configuration of the frequency converter 3 is the same as that of FIG.
[0025]
The Band-III RF amplifying unit 21 receives a received signal from the antenna ANT inputted to the antenna input terminal 2 and outputs an LPF (low-pass filter) 25 that restricts and outputs the high-frequency component, and further outputs it to a predetermined passband. A BPF (band pass filter) 26 that restricts the output of the BPF 26 and an RF amplifier 27 that amplifies the output of the BPF 26. The output side of the RF amplifier 27 is connected to the input terminal t1 of the switch SW.
[0026]
The receiving unit 22 has a BPF (band pass filter) 28 that receives the output of the switch SW, a frequency conversion unit 29 that converts the output of the BPF 28 into an intermediate frequency signal, and a gain for the RF amplifier 27 based on the output of the frequency conversion unit 29. An AGC detector 30 that supplies a control voltage (AGC voltage), an IF amplifier 31 that amplifies the output of the frequency converter 29, and a demodulator 32 that demodulates a signal from the IF amplifier 31 are provided. The frequency converting unit 29 converts a local oscillator (PLL) 33 that outputs a signal having a frequency corresponding to the reception frequency, and an output of the BPF 28 into a signal having an intermediate frequency by mixing the signal from the local oscillator 33 with the local oscillator 33. And a converter 34.
[0027]
The control unit 23 switches the switch SW, turns on / off the power of the frequency conversion unit 3 and the RF amplifier 27, LPF 25 and BPFs 26 and 28 so that the intended Band-III or L-Band can be received. And the oscillation frequency of the local oscillator 33 are controlled.
[0028]
In this configuration, when the L-Band is received, the switch SW is switched to the terminal t2 side. In this case, the received signal from the antenna ANT that is input to the frequency converter 3 via the antenna input terminal 2 is limited to the passband by the BPF 5, amplified by the RF amplifier 6, and further the local oscillator 8 by the frequency converter 7. Is mixed with the signal from the frequency band and converted to a frequency within the Band-III frequency band (174 to 240 MHz). The frequency-converted signal is input to the AGC detector 9 to generate a gain control voltage (AGC voltage) to the RF amplifier 6, and is also input to the receiving unit 22 via the switch SW and demodulated. .
[0029]
At that time, the control unit 23 gives the LPF 25 a control signal whose cutoff frequency is a predetermined frequency of 174 MHz or less, and gives the BPF 26 a control signal whose pass frequency band is 240 MHz or more. As a result, as shown in FIG. 2, the pass band of the LPF 25 becomes a hatched portion 41, and the pass band of the BPF 26 becomes a hatched portion 42. Therefore, the amount of attenuation in the Band-III frequency band by the combination of the LPF 25 and the BPF 26 is about 50 dB in actual measurement.
[0030]
When receiving Band-III, switch SW is switched to the terminal t1 side. In this case, the signal input to the Band-III RF amplifier 21 via the antenna input terminal 2 is limited in the high-frequency component by the LPF 25, limited to the passband by the BPF 26, and further amplified by the RF amplifier 27, and the switch SW Is input to the receiver 22 via.
[0031]
During this time, the gain of the RF amplifier 27 is controlled by the AGC voltage from the receiving unit 22. The control unit 23 gives the LPF 25 a control signal whose cutoff frequency is a predetermined frequency of 240 MHz or higher, and gives the BPF 26 a control signal that makes the band-III received signal pass through. give. As a result, as shown in FIG. 3, the pass band of the LPF 25 becomes a hatched portion 43, and the pass band of the BPF 26 becomes a hatched portion 44. During this time, the frequency converter 3 is turned off by a control signal from the controller 23.
[0032]
The signal input to the receiving unit 22 via the switch SW is limited to the pass band by the BPF 28, and is mixed with the signal from the local oscillator 33 by the frequency converter 34 to be converted into an intermediate frequency signal. The converted signal is supplied to the AGC detection circuit 30 to generate a gain control voltage (AGC voltage) to the RF amplifier 27, amplified by the IF amplifier 31, and demodulated by the demodulator 32.
[0033]
FIG. 4 is a circuit diagram showing the configuration of the LPF 25 and the BPF 26. In the figure, L1, L2 and L3 are coils connected in series with the input terminal IN, C1, C3 and C5 are capacitors respectively connected to the output side of the coils L1, L2 and L3, and D1, D2 And D3 are varactor diodes connected between the other ends of the capacitors C1, C3 and C5 and the ground, and R1, R2 and R3 are respectively connected to the varactor diodes D1, D2 and D3 via the bypass capacitors C2, C4 and C6. These are resistors for applying a control voltage connected in parallel, and the LPF 25 is constituted by these resistors. The coils L1, L2 and L3, the capacitors C1, C3 and C5 and the varactor diodes D1, D2 and D3 form a low-pass filter whose cut-off frequency is applied to the resistors R1, R2 and R3. The voltage can be controlled by changing the capacitances of the varactor diodes D1, D2 and D3 by the control voltage from 23.
[0034]
When receiving the L-Band, the capacitance applied to the resistors R1, R2 and R3 for applying the control voltage is lowered to increase the capacity of the varactor diodes D1, D2 and D3, and the cutoff frequency is set to the lower limit of the Band-III frequency band. Make it lower. During reception of Band-III, the capacitances of the varactor diodes D1, D2, and D3 are reduced by increasing the voltages applied to the resistors R1, R2, and R3, and the cut-off frequency is made higher than the upper limit of the Band-III frequency band.
[0035]
C7 and C8 are capacitors connected in series to the output side of the LPF 25, D4 and C9 are varactor diodes and capacitors inserted in series between the connection points of the capacitors C7 and C8 and the ground, and L4 is a varactor diode D4 and capacitors. A coil connected in parallel with the series circuit of C9, R4, is a resistance for applying a control voltage having one end connected to the connection point of the varactor diode D4 and the capacitor C9 and the other end connected to the ground via the bypass capacitor C10. Yes, and these constitute the BPF 26. A coil L4, capacitors C7, C8 and C9, and a varactor diode D4 constitute a parallel tuning circuit. The tuning frequency can be made variable by applying the control voltage from the control unit 23 to the control voltage applying resistor R4 to change the capacitance of the varactor diode D4. By making the tuning frequency variable, the pass frequency band of the BPF 26 can be changed.
[0036]
During reception of L-Band, the voltage applied to the control voltage application resistor R4 is increased to reduce the capacity of the varactor diode D4, and the pass frequency band (tuning frequency) is set higher than the upper limit of the Band-III frequency band. When receiving Band-III, a voltage that matches the tuning frequency with the frequency is applied to the control voltage application resistor R4.
[0037]
According to the present embodiment, even when the Band-III signal is a strong electric field when the L-Band is received and the isolation of the switch SW is not sufficient, the attenuation effect of the combination of the LPF 25 and the BPF 26 causes the Band-III It is possible to significantly attenuate the signal of the strong electric field and prevent it from being difficult to demodulate the L-Band due to the interference of the strong electric field signal.
[0038]
Further, by cutting off the power supply of the RF amplifier 27 by the power supply control signal from the control unit 23, it is possible to make the RF amplifier 27 act as an attenuator and further increase the amount of attenuation with respect to Band-III.
[0039]
Since not only the LPF 25 and the BPF 26 but also the RF amplifier 27 is inserted between the antenna input terminal 2 and the switch SW, it is necessary to arrange components so that the distance from the antenna input terminal 2 to the switch SW is shortened. Disappears. Furthermore, since the switch SW is not located between the antenna input terminal 2 and the RF amplifier 27, the loss from the antenna input terminal 2 to the RF amplifier 27 can be reduced.
[0040]
By the way, in the receiver of FIG. 1, when it is difficult to demodulate with a strong electric field signal of Band-III during L-Band reception, a variable attenuator is added between the LPF 25 and the BPF 26 in the RF amplification unit 21, It is preferable to increase the signal attenuation of Band-III. Therefore, a receiver according to another embodiment of the present invention has a configuration in which a Band-III RF amplification unit 51 is provided instead of the Band-III RF amplification unit 21 in the configuration of FIG. The Band-III RF amplifying unit 51 includes a variable attenuator 52 added to the Band-III RF amplifying unit 21 between the LPF 25 and the BPF 26 and a voltage converter 53 that outputs a control voltage for adjusting the attenuation. It is. The voltage converter 53 outputs a control voltage based on the AGC signal to the RF amplifier 27 and the power supply control signal. The configuration of other switches SW, frequency conversion unit 3, reception unit 22, control unit 23, and the like are the same as in the case of FIG.
[0041]
In this configuration, when receiving Band-III, the switch SW is switched to the terminal t1 side. In this case, the high-frequency component of the signal input to the Band-III RF amplification unit 51 via the antenna input terminal 2 is limited by the LPF 25, and the amount of attenuation is adjusted by the variable attenuator 52. The attenuation is adjusted so that the signal level corresponding to the signal strength from the antenna ANT is obtained by the voltage obtained by converting the AGC voltage from the Band-III receiving unit 22 to the RF amplifier 27 by the voltage converter 53. The signal whose attenuation is adjusted is limited to the pass band by the BPF 26, further amplified by the RF amplifier 27, and input to the receiving unit 22 via the switch SW. During this time, the gain of the RF amplifier 27 is controlled by the AGC voltage from the receiving unit 22. The control unit 23 gives the LPF 25 a control signal whose cutoff frequency is a predetermined frequency of 240 MHz or higher, and gives the BPF 26 a control signal that makes the band-III received signal pass through. give. During this time, the frequency converter 3 is turned off by a control signal from the controller 23.
[0042]
When receiving L-Band, the switch SW is switched to the terminal t2. In this case, the signal from the antenna ANT input to the antenna input terminal 2 is converted into a frequency within the Band-III frequency band (174 to 240 MHz) in the frequency converter 3. The frequency-converted signal is input to the receiving unit 22 via the switch SW and demodulated. At that time, the control unit 23 gives a control signal for setting the cutoff frequency to a predetermined frequency of 174 MHz or less to the LPF 25, and gives a control signal for setting the pass frequency band to 240 MHz or more to the BPF 26. Further, the control unit 23 turns off the power of the RF amplifier 27 by the power supply control signal and applies the power supply control signal to the voltage converter 53 to cut off the input of the AGC voltage to the voltage converter 53 from the receiving unit 22. The voltage at which the attenuation amount of the variable attenuator 52 is maximized is output from the voltage converter 53 to the variable attenuator 52.
[0043]
At the time of Band-III reception, the control unit 23 not only turns on the power of the RF amplifier 27 by the power control signal, but also applies the power control signal to the voltage converter 53, thereby Is input to the voltage converter 53, and a voltage is applied to the variable attenuator 52 so that the attenuation amount by the variable attenuator 52 becomes an attenuation amount corresponding to the signal intensity input to the antenna input terminal 2. When the signal input to the antenna input terminal 2 is not a strong electric field, the amount of attenuation by the variable attenuator 52 is only the loss due to the insertion of the variable attenuator 52.
[0044]
Therefore, according to the present embodiment, at the time of L-Band reception, in addition to the attenuation effect by the combination of the LPF 25 and the BPF 26, the attenuation effect corresponding to the maximum attenuation amount by the variable attenuator 53 can be given.
[0045]
【The invention's effect】
As described above, according to the present invention, when the signal of the second frequency band is demodulated, the signal of the second frequency band input to the switch means is allowed to pass, and the first frequency band subjected to frequency conversion is used. When the signal is demodulated, a filter for attenuating the signal intensity of the second frequency band input to the switch means is provided before the switch means, so that the adverse effect of the signal of the second frequency band input to the switch means. Therefore, it is possible to prevent the signal in the first frequency band that has been subjected to frequency conversion from being demodulated. At the same time, this filter can be used as a means for passing and extracting only the signal of the second frequency band.
[0046]
In addition, since the amplification means for amplifying the intensity of the signal in the second frequency band is provided before the input to the switch means, the necessity of shortening the distance to the switch means is eliminated, and the degree of freedom of component arrangement is ensured. Can do. In addition, when demodulation of the first frequency band after frequency conversion is performed, the power of the amplifying unit can be turned off to attenuate the signal strength of the second frequency band input to the switch unit. Furthermore, since the amplification means is located in front of the switch means, it is possible to reduce the loss of the received signal up to the amplification means.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a receiver according to an embodiment of the present invention.
2 is a graph showing passbands of LPF 25 and BPF 26 when L-Band is received by the receiver of FIG. 1; FIG.
FIG. 3 is a graph showing passbands of LPF 25 and BPF 26 when Band-III is received in the receiver of FIG. 1;
4 is a circuit diagram showing a configuration of LPF 25 and BPF 26 in the receiver of FIG. 1. FIG.
FIG. 5 is a block diagram showing a configuration of a receiver according to another embodiment of the present invention.
FIG. 6 is a block diagram showing a configuration of a DAB receiver according to a conventional example.
[Explanation of symbols]
1: Band-III receiver, 2: Antenna input terminal, 3: Frequency converter, 4: LPF, 5: BPF, 6: RF amplifier, 7: Frequency converter, 8: Local oscillator, 9: AGC detector, 10: RF amplifier, 11: frequency converter, 12: AGC detector, 13: IF amplifier, 14: demodulator, 15: BPF, 16: RF amplifier, 17: BPF, 18: local oscillator, 19: frequency Converter: 20: Controller, 21: Band-III RF amplifier, 22: Receiver, 23: Controller, 25: LPF, 26: BPF, 27: RF amplifier, 28: BPF, 29: Frequency converter, 30 : AGC detector, 31: IF amplifier, 32: demodulator, 33: local oscillator, 34: frequency converter, 41-44: hatched portion indicating pass band, 51: Band-III RF amplifier, 52: variable attenuation , 53: Voltage change Vessels, ANT: antenna, SW: switch, t1: input terminal, t2: the input terminal.

Claims (6)

Frequency converting means for converting a signal in the first frequency band into a signal in a second frequency band having a frequency lower than the first frequency band, and the input second frequency band signal or the first frequency subjected to the frequency conversion In a receiver including a switch unit that selectively outputs and supplies any one of the signals in the band, and a common demodulation unit that demodulates each signal that is selectively supplied,
When demodulating the second frequency band signal, when passing the second frequency band signal input to the switch means, and demodulating the first frequency band signal subjected to the frequency conversion A filter for attenuating the signal intensity of the second frequency band input to the switch means is provided before the switch means ,
A receiver comprising a low-pass filter having a variable cutoff frequency and a band-pass filter having a variable pass frequency band as the filter . When demodulation is performed on the signal of the first frequency band that has been subjected to the frequency conversion, the cutoff frequency is lowered below the lower limit frequency of the second frequency band, and the lower limit of the frequency of the pass frequency band is set to the first frequency band. by raising than the upper limit of the frequency of the second frequency band receiver according to claim 1, characterized in that the attenuation of the signal strength of the second frequency band by the filter. Amplifying means for amplifying the signal intensity of the second frequency band inputted to the switch means before being inputted to the switch means when the signal of the second frequency band is demodulated; When the signal of the first frequency band subjected to the frequency conversion is demodulated, the signal strength of the second frequency band input to the switch means is attenuated by turning off the power. The receiver according to claim 1 or 2 , characterized in that Variable attenuation means for variably attenuating the signal intensity of the second frequency band input to the switch means is provided in front of the switch means, and the variable attenuation means demodulates the signal of the second frequency band. Sometimes the intensity of the signal in the second frequency band is adjusted according to the intensity, and the second frequency input to the switch means when the signal in the first frequency band subjected to the frequency conversion is demodulated. 4. The receiver according to claim 3 , wherein the intensity of the band signal is attenuated by a predetermined attenuation amount. The variable attenuating means adjusts the signal strength of the second frequency band based on a gain control voltage to the amplifying means when demodulating the signal of the second frequency band. Item 5. The receiver according to Item 4 . Of the frequency conversion means for converting the signal of the first frequency band into the signal of the frequency of the second frequency band, and the input signal of the second frequency band or the signal of the first frequency band subjected to the frequency conversion In a receiver including a switch unit that selectively outputs and supplies either one, and a common demodulation unit that demodulates each signal that is selectively supplied,
Amplifying means for amplifying the signal of the second frequency band before input to the switch means ,
The amplifying means attenuates the signal intensity of the second frequency band input to the switch means when the power is turned off when demodulation of the first frequency band after the frequency conversion is performed. A receiver characterized by that.

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