JPH0969731A - Frequency conversion circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the reflected wave of an image signal from entering the signal output terminal of a mixer and to stabilize the power level of the output signal of a frequency conversion circuit regardless of the frequency of an intermediate frequency signal by providing a resistance line having specific resistance value and a transmission line having specific length between the mixer and a BPF. SOLUTION: A resistor 7a having the resistance value equal to the characteristic impedance of a transmission line connected to a signal output terminal 5 of a mixer 1 and a transmission line 8 connected to the other end of the resistor 7a and having the length of 1/2 wavelength of an image signal are provided between the mixer 1 and a BPF 2. In such a constitution, the image signal is short-circuited by the input terminal of the BPF 2 which transmits a desired signal and attenuates the image signal. Therefore, the image signal is apparently terminated by the resistor 7a at a point ahead of the line 8. As a result, the reflected wave of the image signal is never inputted to the terminal 5 of the mixer 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frequency conversion circuit used in digital communication, radar equipment and the like.

[0002]

2. Description of the Related Art FIG. 16 is a block diagram of a conventional frequency conversion circuit. In the figure, 1 is a mixer, 2 is a band pass filter (hereinafter BPF) that passes a desired signal and attenuates an image signal, 3 is a signal input terminal of the mixer, 4 is a local signal input terminal of the mixer, and 5 is a signal of the mixer. A signal output terminal, 6 is an output terminal of the frequency conversion circuit.

Next, the operation will be described. Apply an intermediate frequency signal (frequency f _IF ) to the signal input terminal 3 of the mixer,
At the same time, when the local oscillator signal (frequency f _LO ) is applied to the local oscillator signal input terminal 4, a signal having a frequency component f _RF of "Equation 1" is generated at the signal output terminal 5.

[0004]

[Equation 1]

Here, in the frequency component f _RF , m = n =
When it is 1, the frequency is "Equation 2".

[0006]

[Equation 2]

Of the two signals of "Equation 2", one is a desired signal and the other is an image signal. This frequency component f _RF
Which passes the desired signal and attenuates the image signal
By inputting to F2, the image signal is attenuated and a desired signal is output from the output terminal 6 of the frequency conversion circuit.

[0008]

In the frequency conversion circuit configured as described above, when the frequency component f _RF is input to the BPF 2 that passes a desired signal and attenuates the image signal, the image signal is reflected by the BPF 2. And is input to the signal output terminal 5 of the mixer. When this reflected wave is remixed by the mixer, conversion loss and spurious levels change. Therefore, in the case of a frequency conversion circuit that swings the frequency of the intermediate frequency signal, there is a problem that the power level of the output signal varies depending on the frequency of the intermediate frequency signal.

The present invention has been made to solve the above problems, and attenuates the reflected wave of the image signal between the signal output terminal of the mixer and the BPF that passes the desired signal and attenuates the image signal. By adding a circuit, it is possible to prevent the reflected wave of the image signal from entering the signal output terminal of the mixer, and to stabilize the power level of the output signal of the frequency conversion circuit so that it does not depend on the frequency of the intermediate frequency signal. To aim.

[0010]

A frequency conversion circuit according to a first embodiment of the present invention has a resistance value between a mixer and a BPF that is equal to a characteristic impedance of a transmission line connected to a signal output terminal of the mixer. It comprises a resistor and a transmission line connected to the other end of the resistor and having a length of a half wavelength of the image signal.

Further, the frequency conversion circuit according to the second embodiment of the present invention includes a series resonance circuit including an inductor and a capacitor connected to the signal output terminal of the mixer between the mixer and the BPF, and the series resonance circuit. A resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end, the other end of which is grounded, and a transmission line having a length of a quarter wavelength of the image signal connected to the output terminal of the mixer. It is equipped with.

A frequency conversion circuit according to a third embodiment of the present invention is such that the series resonance circuit is composed of a distributed constant circuit.

The frequency conversion circuit according to the fourth embodiment of the present invention further includes a high-pass filter (hereinafter referred to as HPF) including a capacitor connected to a signal output terminal of the mixer between the mixer and the BPF, and the HPF. A low-pass filter (hereinafter referred to as L, which is composed of a resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the mixer) and the other end of which is connected to the signal output terminal of the mixer.
PF).

Further, a frequency conversion circuit according to a fifth embodiment of the present invention comprises the above HPF and LPF as distributed constant circuits.

The frequency conversion circuit according to the sixth embodiment of the present invention further includes a series resonance circuit including an inductor and a capacitor connected to the signal output terminal of the mixer between the mixer and the BPF, and the series resonance circuit. It comprises a resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end, the other end of which is grounded, and an LPF including an inductor connected to the signal output terminal of the mixer.

Further, in a frequency conversion circuit according to a seventh embodiment of the present invention, the series resonance circuit and the LPF described above are constituted by a distributed constant circuit.

Further, in the frequency conversion circuit according to the eighth embodiment of the present invention, between the mixer and the BPF, the LPF formed of the inductor connected to the signal output terminal of the mixer and the other end of the LPF are connected. It comprises a resistor having a resistance value equal to the characteristic impedance of the transmission line, the other end of which is grounded, and an HPF made up of a capacitor connected to the signal output terminal of the mixer.

Further, a frequency conversion circuit according to a ninth embodiment of the present invention comprises the above LPF and HPF by distributed constant circuits.

Further, the frequency conversion circuit according to the tenth embodiment of the present invention includes a series resonance circuit including an inductor and a capacitor connected to the signal output terminal of the mixer between the mixer and the BPF, and the series resonance circuit. A resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end, the other end of which is grounded, and an HPF including a capacitor connected to the signal output terminal of the mixer are provided.

The frequency conversion circuit according to the eleventh embodiment of the present invention is such that the series resonance circuit and the HPF are constituted by a distributed constant circuit.

The frequency conversion circuit according to the twelfth embodiment of the present invention further includes an HPF including a capacitor connected between the mixer and the BPF, the capacitor being connected to the signal output terminal of the mixer.
A resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the HPF, an LPF including an inductor connected to the signal output terminal of the mixer and having the other end connected to the resistor, and the LPF And a transmission line having a length of a half wavelength of the image signal connected to the other end.

Further, a frequency conversion circuit according to a thirteenth embodiment of the present invention comprises the above HPF and LPF as distributed constant circuits.

Further, in a frequency conversion circuit according to a fourteenth embodiment of the present invention, between a mixer and a BPF, an LPF formed of an inductor connected to a signal output terminal of the mixer and a transmission connected to the other end of the LPF. A resistor having a resistance value equal to the characteristic impedance of the line, an HPF composed of a capacitor connected to the signal output terminal of the mixer and having the other end connected to the resistor, and an image signal connected to the other end of the HPF. And a transmission line having a length of one-half wavelength.

Further, a frequency conversion circuit according to the fifteenth embodiment of the present invention is such that the above LPF and HPF are constituted by distributed constant circuits.

[0025]

According to the first embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal is short-circuited at the input end of the BPF for passing the desired signal and for attenuating the image signal. , Half of the image signal
It is apparently terminated by a resistor before the transmission line of the wavelength length. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the second embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal is short-circuited at the input end of the BPF which allows a desired signal to pass therethrough and attenuates the image signal. Therefore, it is apparently open in front of the transmission line having a length of ¼ wavelength of the image signal. Therefore, the image signal is absorbed by the series resonant circuit and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the third embodiment of the present invention, the series resonance circuit is constituted by the distributed constant circuit, and therefore, the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the second embodiment.

Further, according to the fourth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f ₊ is apparently open before the LPF.
Therefore, the image signal f ₊ passes through the HPF and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the fifth embodiment of the present invention, the LPF and HPF are constituted by the distributed constant circuit, so that the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the fourth embodiment.

Further, according to the sixth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f ₊ is apparently open before the LPF.
Therefore, the image signal f ₊ is absorbed by the series resonance circuit and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the seventh embodiment of the present invention, by configuring the LPF and the series resonance circuit by the distributed constant circuit, the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the sixth embodiment. To be

Further, according to the eighth embodiment of the present invention, in the frequency conversion circuit constructed as described above, the image signal f _- is apparently open before the HPF.
Therefore, the image signal f ₋ passes through the LPF and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the ninth embodiment of the present invention, the above HPF and LPF are constituted by the distributed constant circuit, so that the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the eighth embodiment.

According to the tenth embodiment of the present invention, in the frequency conversion circuit constructed as described above, the image signal f _- is apparently open before the HPF. Therefore, the image signal f ₋ is absorbed by the series resonant circuit and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the eleventh embodiment of the present invention, the above HPF and the series resonance circuit are constituted by the distributed constant circuit, so that the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the tenth embodiment. To be

According to the twelfth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f ₊ is apparently open before the LPF. Therefore, the image signal f ₊ passes through the HPF, but the image signal is short-circuited at the input end of the BPF that passes the desired signal and attenuates the image signal.
It is apparently terminated by a resistor in front of the transmission line having a half wavelength of the image signal. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the thirteenth embodiment of the present invention, by configuring the above-mentioned LPF and HPF by the distributed constant circuit, the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the twelfth embodiment.

According to the fourteenth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f _- is apparently open before the HPF. Therefore, the image signal f ₋ passes through the LPF, but the image signal is short-circuited at the input end of the BPF that passes the desired signal and attenuates the image signal.
It is apparently terminated by a resistor in front of the transmission line having a half wavelength of the image signal. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the fifteenth embodiment of the present invention, by configuring the HPF and the LPF by the distributed constant circuit, the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the fourteenth embodiment.

[0040]

【Example】

Embodiment 1 FIG. 1 is a diagram showing a first embodiment of the present invention,
In the figure, 1 to 6 are the same parts as the conventional device, and 7a
Is a resistor, and 8 is a transmission line having a half wavelength of the image signal.

In the frequency conversion circuit configured as described above, an intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, a local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. Where f ₊ is the desired signal,
The case where f _- is an image signal will be described. The same applies to the opposite case. Among the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is short-circuited at the input end of the BPF 2, and therefore the image signal Half
It is apparently terminated by a resistor 7a before the transmission line 8 having the wavelength length. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 2. 2 is a diagram showing a second embodiment of the present invention, in which 1 to 6 are the same parts as in the conventional device, 7a is a resistor, and 9 is the transmission of a quarter wavelength of an image signal. A line, 10 is an inductor, 11 is a capacitor, and 12a is a series resonance circuit.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. Where f ₊ is the desired signal,
The case where f _- is an image signal will be described. The same applies to the opposite case. Among the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is short-circuited at the input end of the BPF 2, and therefore the image signal One quarter
It is apparently open in front of the transmission line 9 having the wavelength length. Therefore, the image signal is absorbed by the series resonance circuit 12a and terminated by the resistor 7a. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 3. 3 is a diagram showing a third embodiment of the present invention. In the figure, 1 to 6 are the same parts as in the conventional device, 7b is a resistor, and 9 is a transmission of a quarter wavelength of an image signal. The line 12b is a series resonance circuit.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. Where f ₊ is the desired signal,
The case where f _- is an image signal will be described. The same applies to the opposite case. Among the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is short-circuited at the input end of the BPF 2, and therefore the image signal One quarter
It is apparently open in front of the transmission line 9 having the wavelength length. Therefore, the image signal is absorbed by the series resonance circuit 12b and terminated by the resistor 7b. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 4. 4 is a diagram showing a fourth embodiment of the present invention, in which 1 to 6 are the same parts as in the conventional device, 7a is a resistor, 10 is an inductor, 11 is a capacitor, 13a is an LPF, and 14a is an HPF. Is.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
_- , When the image signal is f ₊ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₊ is apparently open before the LPF 13a. Therefore, the image signal f ₊ is the HPF 14
It passes through a and is terminated by the resistor 7a. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Embodiment 5 FIG. FIG. 5 is a diagram showing a fifth embodiment of the present invention, in which 1 to 6 are the same parts as in the conventional device, 7b is a resistor, 13b is an LPF, and 14b is an HP.
F.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5.
Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is a desired signal,
The other is the image signal. In this embodiment, the desired signal is f ₋ and the image signal is f ₊ . Of the frequency component f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal,
The image signal f ₊ is apparently open before the LPF 13b. Therefore, the image signal f ₊ is HPF1
4b and is terminated by a resistor 7b. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 6. 6 is a diagram showing a sixth embodiment of the present invention, in which 1 to 6 are the same parts as in the conventional device, 7a is a resistor, 10 is an inductor, 11 is a capacitor, 12a is a series resonance circuit, and 13a. Is LPF.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
_- , When the image signal is f ₊ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₊ is apparently open before the LPF 13a. Therefore, the image signal f ₊ is absorbed by the series resonance circuit 12a and terminated by the resistor 7a. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Embodiment 7 FIG. 7 is a diagram showing a seventh embodiment of the present invention, in which 1 to 6 are the same parts as in the conventional device, 7b is a resistor, 12b is a series resonant circuit, and 13b.
Is LPF.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
_- , When the image signal is f ₊ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₊ is apparently open before the LPF 13b. Therefore, the image signal f ₊ is absorbed by the series resonance circuit 12b and terminated by the resistor 7b. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 8. 8 is a diagram showing an eighth embodiment of the present invention, in which 1 to 6 are the same parts as in the conventional device, 7a is a resistor, 10 is an inductor, 11 is a capacitor, 13a is an LPF, and 14a is an HPF. Is.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
₊ , When the image signal is f ₋ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is apparently open before the HPF 14a. Therefore, the image signal f ₋ is the LPF 13
It passes through a and is terminated by the resistor 7a. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Embodiment 9 FIG. FIG. 9 is a diagram showing a ninth embodiment of the present invention. In the figure, 1 to 6 are the same parts as the conventional device, 7b is a resistor, 13b is an LPF, and 14b is an HP.
F.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
₊ , When the image signal is f ₋ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is apparently open before the HPF 14a. Therefore, the image signal f ₋ is the LPF 13
It passes through a and is terminated by the resistor 7a. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 10. FIG. 10 is a first embodiment of the present invention.
It is a figure which shows 0, 1-6 is a part similar to a conventional device in the figure, 7a is a resistor, 10 is an inductor, 11
Is a capacitor, 12a is a series resonance circuit, and 14a is an HPF.
It is.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
₊ , When the image signal is f ₋ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is apparently open before the HPF 14a. Therefore, the image signal f _- is absorbed by the series resonance circuit 12a and terminated by the resistor 7a. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 11. FIG. 11 is a first embodiment of the present invention.
FIG. 1 is a diagram showing 1 in which 1 to 6 are the same parts as in the conventional device, 7b is a resistor, 12b is a series resonance circuit,
14b is HPF.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
₊ , When the image signal is f ₋ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is apparently open before the HPF 14b. Therefore, the image signal f _- is absorbed by the series resonance circuit 12b and terminated by the resistor 7b. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Embodiment 12 FIG. FIG. 12 is a first embodiment of the present invention.
FIG. 2 is a diagram showing 2, in which 1 to 6 are the same parts as in the conventional device, 7a is a resistor, 8 is a half wavelength of the image signal, transmission line 10 is an inductor, and 11 is A condenser, 13a is an LPF, and 14a is an HPF.

In the frequency conversion circuit configured as described above, an intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, a local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
_- , When the image signal is f ₊ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₊ is apparently open before the LPF 13a. Therefore, the image signal f ₊ is the HPF 14
Although it passes through a, the image signal is short-circuited at the input end of the BPF 2, so that it is apparently terminated by the resistor 7a before the transmission line 8 having a length of half the wavelength of the image signal. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Example 13. FIG. 13 shows Embodiment 1 of the present invention.
FIG. 3 is a diagram showing 3 in which 1 to 6 are the same parts as in the conventional device, 7b is a resistor, 8 is a transmission line having a half wavelength of the image signal, 13b is an LPF, and 14b is HPF.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
_- , When the image signal is f ₊ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₊ is apparently open before the LPF 13b. Therefore, the image signal f ₊ is the HPF 14
Although it passes through b, since the image signal is short-circuited at the input end of the BPF 2, it is apparently terminated by the resistor 7b in front of the transmission line 8 having a half wavelength of the image signal. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Embodiment 14 FIG. FIG. 14 is a first embodiment of the present invention.
FIG. 4 is a diagram showing 4, in which 1 to 6 are the same parts as in the conventional device, 7 a is a resistor, 8 is a transmission line having a half wavelength of an image signal, 10 is an inductor, and 11 is A condenser, 13a is an LPF, and 14a is an HPF.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
₊ , When the image signal is f ₋ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is apparently open before the HPF 14a. Therefore, the image signal f ₋ is the LPF 13
Although it passes through a, the image signal is short-circuited at the input end of the BPF 2, so that it is apparently terminated by the resistor 7a before the transmission line 8 having a length of half the wavelength of the image signal. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

Embodiment 15 FIG. FIG. 15 is a first embodiment of the present invention.
FIG. 5 is a diagram showing 5, in which 1 to 6 are the same parts as in the conventional device, 7b is a resistor, 8 is a transmission line having a half wavelength of the image signal, 13b is an LPF, and 14b is HPF.

In the frequency conversion circuit configured as described above, the intermediate frequency signal (frequency f _IF ) is applied to the signal input terminal 3 of the mixer, and at the same time, the local oscillation signal (frequency f _LO ) is applied to the local oscillation signal input terminal 4. Is applied, a signal having the frequency component f _RF of the above "Numerical formula 1" is generated at the signal output terminal 5. Here, of the frequency components f _RF , one of the two signals of the frequency “Equation 2” when m = n = 1 is the desired signal and the other is the image signal. In this embodiment, the desired signal is f
₊ , When the image signal is f ₋ . Of the frequency components f _RF input to the BPF 2 that passes a desired signal from the signal output terminal 5 of the mixer and attenuates the image signal, the image signal f ₋ is apparently open before the HPF 14b. Therefore, the image signal f ₋ is the LPF 13
Although it passes through b, since the image signal is short-circuited at the input end of the BPF 2, it is apparently terminated by the resistor 7b in front of the transmission line 8 having a half wavelength of the image signal. By inputting this frequency component f _RF into the BPF 2, the mixing spurious is suppressed, the desired signal is stabilized without depending on the frequency of the intermediate frequency signal, and is output from the output terminal 6 of the frequency conversion circuit.

[0070]

According to the first embodiment of the present invention, in the frequency conversion circuit configured as described above, a BP that passes a desired image signal and attenuates the image signal is used.
Since the input terminal of F is short-circuited, 2 of the image signal
It is apparently terminated by a resistor before the transmission line having a length of one-half wavelength. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the second embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal is short-circuited at the input end of the BPF that allows the desired signal to pass and attenuates the image signal. Therefore, it is apparently open in front of the transmission line having a length of ¼ wavelength of the image signal. Therefore, the image signal is absorbed by the series resonant circuit and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the third embodiment of the present invention, the series resonance circuit is constituted by the distributed constant circuit, and thus the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the second embodiment.

Further, according to the fourth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f ₊ is apparently open before the LPF.
Therefore, the image signal f ₊ passes through the HPF and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the fifth embodiment of the present invention, the LPF and HPF are constituted by the distributed constant circuit, so that the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the fourth embodiment.

According to the sixth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f ₊ is apparently open before the LPF.
Therefore, the image signal f ₊ is absorbed by the series resonance circuit and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the seventh embodiment of the present invention, the LPF and the series resonance circuit are constituted by the distributed constant circuit, and thus the same effect can be obtained for the frequency conversion circuit having a higher frequency than the sixth embodiment. To be

Further, according to the eighth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f _- is apparently open before the HPF.
Therefore, the image signal f ₋ passes through the LPF and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the ninth embodiment of the present invention, the HPF and the LPF are constituted by the distributed constant circuit, and the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the eighth embodiment.

According to the tenth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f _- is apparently open before the HPF. Therefore, the image signal f ₋ is absorbed by the series resonant circuit and is terminated by the resistor. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the eleventh embodiment of the present invention, the HPF and the series resonance circuit are constituted by the distributed constant circuit, and thus the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the tenth embodiment. To be

Further, according to the twelfth embodiment of the present invention, in the frequency conversion circuit constructed as described above, the image signal f ₊ is apparently open before the LPF. Therefore, the image signal f ₊ passes through the HPF, but the image signal is short-circuited at the input end of the BPF that passes the desired signal and attenuates the image signal.
It is apparently terminated by a resistor before the transmission line having a length of half the wavelength of the image signal. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer.
From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the thirteenth embodiment of the present invention, by constructing the LPF and HPF by the distributed constant circuit, the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the twelfth embodiment.

According to the fourteenth embodiment of the present invention, in the frequency conversion circuit configured as described above, the image signal f _- is apparently open before the HPF. Therefore, the image signal f ₋ passes through the LPF, but the image signal is short-circuited at the input end of the BPF that passes the desired signal and attenuates the image signal.
It is apparently terminated by a resistor in front of the transmission line having a half wavelength of the image signal. Therefore, the reflected wave of the image signal is not input to the signal output terminal of the mixer. From the above, the power level of the output signal of the frequency conversion circuit is stabilized without depending on the frequency of the intermediate frequency signal.

Further, according to the fifteenth embodiment of the present invention, the HPF and LPF are constituted by the distributed constant circuit, and the same effect can be obtained for the frequency conversion circuit having a higher frequency than that of the fourteenth embodiment.

[Brief description of drawings]

FIG. 1 is a diagram showing a first embodiment of a frequency conversion circuit according to the present invention.

FIG. 2 is a diagram showing a second embodiment of the frequency conversion circuit according to the present invention.

FIG. 3 is a diagram showing a third embodiment of the frequency conversion circuit according to the present invention.

FIG. 4 is a diagram showing a fourth embodiment of the frequency conversion circuit according to the present invention.

FIG. 5 is a diagram showing a fifth embodiment of the frequency conversion circuit according to the present invention.

FIG. 6 is a diagram showing a sixth embodiment of the frequency conversion circuit according to the present invention.

FIG. 7 is a diagram showing a frequency conversion circuit according to a seventh embodiment of the present invention.

FIG. 8 is a diagram showing an eighth embodiment of the frequency conversion circuit according to the present invention.

FIG. 9 is a diagram showing a ninth embodiment of the frequency conversion circuit according to the present invention.

FIG. 10 is a first embodiment of the frequency conversion circuit according to the present invention.
It is a figure which shows 0.

FIG. 11 is a first embodiment of the frequency conversion circuit according to the present invention.
It is a figure which shows 1.

FIG. 12 is a first embodiment of the frequency conversion circuit according to the present invention.
FIG.

FIG. 13 is a first embodiment of the frequency conversion circuit according to the present invention.
FIG.

FIG. 14 is a first embodiment of the frequency conversion circuit according to the present invention.
FIG.

FIG. 15 is a first embodiment of the frequency conversion circuit according to the present invention.
It is a figure which shows 5.

FIG. 16 is a diagram showing a conventional frequency conversion circuit.

[Explanation of symbols]

1 mixer, 2 BPF for passing a desired signal and attenuating an image signal, 3 mixer signal input terminal, 4 mixer local signal input terminal, 5 mixer signal output terminal, 6
Output terminal of frequency conversion circuit, 7 resistor, 8 transmission line having a half wavelength of image signal, 9 transmission line having a quarter wavelength of image signal, 10 inductor, 11 capacitor, 12 Series resonant circuit, 13 L
PF, 14 HPF.

Claims (15)

[Claims] 1. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for allowing a desired signal to pass therethrough and attenuating an image signal, wherein a mixer and a bandpass filter are provided between the mixer and the bandpass filter. A resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the signal output terminal of the mixer, and a transmission line having a half wavelength of the image signal connected to the other end of the resistor. A frequency conversion circuit comprising: 2. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein a frequency conversion circuit is provided between the mixer and the bandpass filter. A series resonance circuit composed of an inductor and a capacitor connected to the signal output terminal of the mixer, and a resistor having the other end connected to the other end of the series resonance circuit and having a resistance value equal to the characteristic impedance of the transmission line grounded. And a transmission line having a length of a quarter wavelength of the image signal connected to the output terminal of the mixer. 3. The frequency conversion circuit according to claim 2, wherein the series resonance circuit is composed of a distributed constant circuit. 4. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein a frequency conversion circuit is provided between the mixer and the bandpass filter. A high-pass filter composed of a capacitor grounded to the signal output terminal of the mixer, and a resistor having the other end having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the high-pass filter. And a low-pass filter including an inductor connected to the signal output terminal of the mixer. 5. The frequency conversion circuit according to claim 4, wherein the high-pass filter and the low-pass filter are constituted by a distributed constant circuit. 6. A frequency conversion circuit comprising a mixer and a bandpass filter connected to the signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein a frequency conversion circuit is provided between the mixer and the bandpass filter. A series resonance circuit composed of an inductor and a capacitor grounded to the signal output terminal of the mixer, and a resistor having the other end having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the series resonance circuit. And a low-pass filter including an inductor connected to the signal output terminal of the mixer. 7. The frequency conversion circuit according to claim 6, wherein the series resonance circuit and the low-pass filter are constituted by a distributed constant circuit. 8. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein the mixer and the bandpass filter are provided between the mixer and the bandpass filter. , A low-pass filter consisting of an inductor connected to the signal output terminal of the mixer, and a resistor whose other end has a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the low-pass filter. And a high pass filter including a capacitor connected to the signal output terminal of the mixer. 9. The frequency conversion circuit according to claim 8, wherein the low-pass filter and the high-pass filter are constituted by a distributed constant circuit. 10. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein a frequency conversion circuit is provided between the mixer and the bandpass filter. , A series resonance circuit consisting of an inductor and a capacitor connected to the signal output terminal of the mixer, and a resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the series resonance circuit, the other end of which is grounded. And a high pass filter including a capacitor connected to the signal output terminal of the mixer. 11. The frequency conversion circuit according to claim 10, wherein the series resonance circuit and the high-pass filter are constituted by a distributed constant circuit. 12. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein a mixer and a bandpass filter are provided between the mixer and the bandpass filter. , A high-pass filter consisting of a capacitor connected to the signal output terminal of the mixer, a resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the high-pass filter, and the mixer A low-pass filter composed of an inductor connected to the signal output terminal and the other end connected to a resistor; and a transmission line having a length of one-half wavelength of the image signal connected to the other end of the low-pass filter. A frequency conversion circuit comprising: 13. The frequency conversion circuit according to claim 12, wherein the high-pass filter and the low-pass filter are constituted by a distributed constant circuit. 14. A frequency conversion circuit comprising a mixer and a bandpass filter connected to a signal output terminal of the mixer for passing a desired signal and for attenuating an image signal, wherein a frequency conversion circuit is provided between the mixer and the bandpass filter. , A low-pass filter consisting of an inductor connected to the signal output terminal of the mixer, a resistor having a resistance value equal to the characteristic impedance of the transmission line connected to the other end of the low-pass filter, and the mixer A high-pass filter composed of a capacitor connected to the signal output terminal and the other end connected to a resistor; and a transmission line having a half wavelength of the image signal connected to the other end of the high-pass filter. A frequency conversion circuit comprising: 15. The frequency conversion circuit according to claim 14, wherein the low-pass filter and the high-pass filter are constituted by a distributed constant circuit.