JPH06152469A - Synthesizer receiver - Google Patents

Abstract

PURPOSE:To simplify a circuit and to improve interference to the circuit caused by a transmitting signal by preparing a local oscillation frequency signal and a transmission carrier frequency signal with one PLL circuit, reference frequency oscillator and mixer. CONSTITUTION:The output signal of a voltage controlled oscillator(VCO) constituting a PLL circuit and the output signal of a second reference frequency oscillator 25 are mixed by a mixer 26, and an adding frequency component and a subtracting frequency component are prepared. Then, the adding frequency component is extracted by a first band pass filter(BPF) 27 and defined as a reception local oscillation frequency signal, the subtracting frequency component is extracted by a second BPF 28 and defined as a transmission carrier frequency signal, and a PLL loop is formed by inputting the output signal of one filter to a frequency divider 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a synthesizer receiver used in a cordless telephone, and more particularly to a synthesizer receiver in which a local oscillator circuit for reception and a carrier wave oscillator circuit for transmission are realized by one PLL circuit.

[0002]

2. Description of the Related Art FIG. 3 shows, for example, JP-A-62-98925.
FIG. 6 is a block diagram showing a configuration of a conventional synthesizer receiver disclosed in Japanese Patent Publication No.

The synthesizer receiver has an antenna 1 for radiating and receiving radio waves, and a receiving bandpass filter 2 for passing only a predetermined band is connected to the antenna 1. A reception amplifier 3 is connected to the reception bandpass filter 2, and the reception amplifier 3 outputs the output of the reception amplifier 3 and a reception synthesizer circuit 16 described later.
A mixer 4 for mixing with the output of is connected. Furthermore,
The mixer 4 is connected to an intermediate frequency bandpass filter 5 that passes only the intermediate frequency, and the intermediate frequency bandpass filter 5 generates an output of the intermediate frequency bandpass filter 5 and a second local oscillation circuit 6. A mixer 7 for mixing a predetermined oscillation signal to be connected is connected.

The mixer 7 is connected to a demodulation circuit 8 which amplifies the second intermediate frequency signal output from the mixer 7 to limit the amplitude, and then FM-detects and reproduces an audio signal. The circuit 8 includes a handset 1 having a speaker (not shown) for converting a demodulated voice signal into voice.
0 is connected. Further, the handset 10 has a built-in microphone (not shown) for converting voice into a voice signal, and the handset 10 modulates the voice signal converted by the microphone to perform processing such as bandwidth and amplitude width limitation. The signal processing circuit 17 and the system controller 9 that controls the reception synthesizer circuit 16 and the transmission synthesizer circuit 22 are connected.

Further, the receiving synthesizer circuit 16 includes a voltage controlled oscillator 11 for controlling an oscillation frequency by a voltage,
Frequency divider 12 for dividing the output frequency of voltage controlled oscillator 11
And a phase comparator 13 that generates an error voltage by comparing the output phase of the first reference oscillator 15 that generates the first reference frequency with the output phase of the frequency divider 12, and the error voltage of the phase comparator 13. The low pass filter 14 integrates and applies to the voltage controlled oscillator 11. Further, the transmission synthesizer circuit 22 includes a voltage controlled oscillator 18 that controls an oscillation frequency by a voltage, a frequency divider 19 that divides an output frequency of the voltage controlled oscillator 18, and a first reference oscillator that generates a first reference frequency. A phase comparator 20 for comparing the output phase of 15 and the output phase of the frequency divider 19 to generate an error voltage, and a voltage controlled oscillator 18 for integrating the error voltage of the phase comparator 20.
And a low-pass filter 21 applied to the.

On the other hand, the modulation signal processing circuit 17 is connected to a voltage controlled oscillator 18, and the voltage controlled oscillator 18 is connected to an amplifier 23 for amplifying its output.
A transmission bandpass filter 24 that removes unnecessary components is connected to the amplifier 23, and the transmission bandpass filter 24 is connected to the antenna 1.

Next, the operation will be described.

The antenna 1 picks up a radio wave radiated in space, converts it into a high frequency signal and sends it to the reception band pass filter 2. Then, the high-frequency signal has its unnecessary components removed by the bandpass filter 2, is sent to the amplifier 3, and is amplified by the amplifier 3. Then, the high frequency signal amplified by the amplifier 3 is sent to the mixer 4, and the mixer 4 mixes this high frequency signal with the local oscillation signal sent from the reception synthesizer circuit 16 to obtain the sum or difference frequency component of each signal. Convert to.

Furthermore, the frequency component of the difference is selected as the first intermediate frequency signal by the intermediate frequency band pass filter 5 and sent to the mixer 7, and the mixer 7 receives the first intermediate frequency signal and the second local oscillator. The oscillating signal from 6 is mixed and converted into a second intermediate frequency signal. Then, the second intermediate frequency signal is input to the demodulation circuit 8, and the demodulation circuit 8 amplifies and limits the amplitude of the second intermediate frequency signal, and then performs FM detection and sends it to the transmission circuit of the handset 10. Then, the handset 10 converts the voice signal from the demodulation circuit 8 into a voice with a built-in speaker and speaks. At the same time, the built-in microphone picks up the voice and converts it into a voice signal.

On the other hand, when setting the reception CH (channel), the frequency division ratio of the frequency divider 12 is set to a predetermined N _R by the data from the system controller 9. Then, the frequency-divided output signal of the frequency divider 12 and the output signal of the first reference oscillator 15 are phase-compared by the phase comparator 13, and the phase comparator 13 generates the error signal. Then, the low-pass filter 14 integrates the error signal and then applies the error signal to the voltage controlled oscillator 11. In a steady state, the phase error of each signal disappears, and the output signal frequency of the synthesizer circuit 16 is F _RL = N _R · F _r And the subtraction frequency component of the reception mixer 4 becomes the first intermediate frequency. Here, F _r is the oscillation frequency of the first reference oscillator 15.

Similarly, the transmission CH (channel) is set by the transmission synthesizer circuit 22 including the transmission voltage controlled oscillator 18, the transmission frequency divider 19, and the transmission phase comparator 2.
0, a PLL loop is formed by the transmission low-pass filter 21, performs the same operation as the reception side synthesizer circuit 16, and determines the transmission frequency F _OT = N _T · F _r by setting the transmission CH division ratio N _T. You can

Although the local oscillation frequency F _RL for reception and the transmission frequency F _OT can be set as described above, since the frequency difference between the reception frequency F _R and the transmission frequency F _OT is generally determined by the Radio Law, If one is decided, the other is automatically decided.

On the other hand, the modulation signal processing circuit 17 performs signal processing such as bandwidth and amplitude limitation on the voice signal from the handset 10, and applies the signal-processed voice signal to the modulation element of the transmission voltage controlled oscillator 18. Perform FM modulation. And
The output signal of the transmission voltage controlled oscillator 18 that has undergone FM modulation is amplified by the transmission amplifier 23 and radiated into space.

[0014]

As described above, the conventional synthesizer receiver is composed of the two synthesizer circuits of the local oscillator for reception and the carrier wave oscillator for transmission, so that the frequency can be independently set. Since the scale is large and complicated, there are drawbacks such as a large component cost and a large mounting area. Further, in the mobile communication device, since the frequency interval between the transmission frequency and the reception frequency is defined, the fact that the frequency can be arbitrarily set is not a great effect.

The present invention has been made in order to solve the above problems, and mixes the output signal of the voltage controlled oscillator of one PLL circuit and the output signal of the second reference frequency oscillator to mix their frequencies. Synthesizer reception that can simplify the circuit configuration by creating the addition frequency component and the subtraction frequency component of the above and determining the voltage controlled oscillator frequency and the second reference frequency oscillator frequency so that the local oscillation frequency signal and the transmission carrier frequency signal are obtained. The purpose is to get the opportunity.

[0016]

According to a first aspect of the present invention, there is provided a synthesizer receiver comprising: a voltage controlled oscillator for controlling an oscillation frequency by a voltage; a frequency divider for dividing an output frequency of the voltage controlled oscillator; A first reference oscillator that generates one reference frequency, a second reference oscillator that generates a second reference frequency, and an error voltage by comparing the output phase of the first reference oscillator and the output phase of the frequency divider. The generated phase comparator, the first filter for integrating the error voltage of the phase comparator, the output signal of the voltage controlled oscillator, and the output signal of the second reference oscillator are mixed, the sum of the frequencies of both output signals. And a subtraction frequency component signal having a frequency component of a difference between the frequencies of both outputs, and a mixer output from the mixer, Or a second filter for extracting one of the subtracted frequency component signal, and the second filter output or the voltage controlled oscillator output is used as the input signal of the frequency divider. is there.

According to a second aspect of the present invention, there is provided a synthesizer receiver comprising a voltage-controlled oscillator for voltage-controlling so as to oscillate an oscillation frequency which is ½ of a frequency obtained by adding a transmission frequency and a local oscillation frequency. A divider for dividing the output frequency, a first reference oscillator for generating a first reference frequency, a second reference oscillator for generating a second reference frequency, an output phase of the first reference oscillator and the divider. A phase comparator for generating an error voltage by comparing the output phase of the voltage generator, the output signal of the voltage controlled oscillator, and the output signal of the second reference oscillator are mixed, and the frequency component of the sum of the frequencies of both output signals is mixed. And a subtraction frequency component signal having a frequency component of a difference between the frequencies of the two outputs, and a mixer output from the mixer, the addition frequency component signal A second filter for extracting one of the arithmetic frequency component signal and the second filter, and the second filter output or the second voltage controlled oscillator output is used as the input signal of the frequency divider. It is a thing.

According to a third aspect of the present invention, a synthesizer receiver has a voltage controlled oscillator for controlling an oscillation frequency by a voltage, a frequency divider for dividing an output frequency of the voltage controlled oscillator, and a transmission frequency for a local oscillation frequency. A second reference oscillator that generates a second reference frequency that is a frequency obtained by subtracting the local oscillation frequency from the subtracted frequency or the transmission frequency, an output signal of the voltage controlled oscillator, and an output signal of the second reference oscillator are mixed. A mixer for outputting an addition frequency component signal having a frequency component of a sum of frequencies of both output signals and a subtraction frequency component signal having a frequency component of a difference between frequencies of the two outputs, and an output signal of the mixer. A second filter for extracting one of the addition frequency component signal or the subtraction frequency component signal, and a second filter output. The other is characterized in that the input signal of the frequency divider of the first voltage controlled oscillator output.

According to a fourth aspect of the present invention, there is provided a synthesizer receiver in which a voltage controlled oscillator for controlling an oscillation frequency by a voltage, a frequency divider for dividing an output frequency of the voltage controlled oscillator, and a first reference frequency are generated. The first reference oscillator, the second reference oscillator that generates the Nth harmonic of the first reference frequency, the output signal of the voltage controlled oscillator, and the output signal of the second reference oscillator. A mixer for outputting an addition frequency component signal having a frequency component of a sum of frequencies and a subtraction frequency component signal having a frequency component of a difference between frequencies of both outputs; and the addition frequency component signal from the output signal of the mixer, Component signal or the subtracted frequency component signal,
And a second filter for extracting one of the signals, and the second filter output or the first voltage controlled oscillator output is used as the input signal of the frequency divider.

According to a fifth aspect of the present invention, there is provided a synthesizer receiver in which a voltage controlled oscillator for controlling an oscillation frequency by a voltage, a variable frequency oscillator for frequency controlled by an error component of an intermediate frequency, and an output signal of the voltage controlled oscillator. ,
An output signal of the second reference oscillator is mixed, and an addition frequency component signal having a frequency component of the sum of the frequencies of both output signals,
A mixer that outputs a subtraction frequency component signal having a frequency component of a difference between the frequencies of the two outputs, and an output signal of the mixer, the addition frequency component signal or the subtraction frequency component signal, either one of And a second filter for extracting a signal.

[0021]

In the synthesizer receiver according to the present invention, the output frequency of the voltage controlled oscillator is divided by the frequency divider, the first reference frequency is generated by the first reference oscillator, and the output phase of the first reference oscillator and the above-mentioned divided frequency are generated. The output voltage of the frequency divider is compared with the comparator to generate an error voltage, and the error voltage of the phase comparator is integrated by the first filter. A second reference frequency is generated by the second reference oscillator, the output of the voltage controlled oscillator and the output of the second reference oscillator are mixed by a mixer, and the addition or subtraction frequency component of both outputs is mixed by the mixer. The second filter output or the voltage controlled oscillator output is used as the input signal of the frequency divider. This allows the output signal of one PLL circuit to be mixed with the second oscillator output signal, and the addition frequency component and the subtraction frequency component to be the local oscillation signal and the transmission carrier signal, which simplifies the circuit.
The cost can be reduced. Further, the oscillator circuit using AFC for feeding back the low frequency component of the FM demodulated signal can be used, and the cost can be reduced.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

Embodiment 1 As shown in FIG. 1, a synthesizer receiver has an antenna 1 for radiating and receiving radio waves, and the antenna 1 has a receiving band pass filter 2 for passing only a predetermined band.
Are connected. Then, the reception bandpass filter 2
Is connected to the receiving amplifier 3, and the receiving amplifier 3 is connected to the mixer 4 which mixes the output of the receiving amplifier 3 and the output of the synthesizer circuit 34 described later. Further, the mixer 4 is connected with an intermediate frequency bandpass filter 5 that passes only the intermediate frequency. The intermediate frequency bandpass filter 5 outputs the output of the intermediate frequency bandpass filter 5 and a second reference oscillator. A mixer 7 for mixing a predetermined oscillation signal generated by the second local oscillation circuit 6 is connected.

The mixer 7 is connected to a demodulation circuit 8 which amplifies the second intermediate frequency signal output from the mixer 7 to limit its amplitude and then FM-detects and reproduces an audio signal. The circuit 8 includes a handset 1 having a speaker (not shown) for converting a demodulated voice signal into voice.
0 is connected. Further, the handset 10 has a built-in microphone (not shown) for converting voice into a voice signal, and the handset 10 modulates the voice signal converted by the microphone to perform processing such as bandwidth and amplitude width limitation. The signal processing circuit 17 and the system controller 9 that controls the synthesizer circuit 34 are connected.

Further, the synthesizer circuit 34 includes a voltage controlled oscillator 11 which controls the oscillation frequency by a voltage, a second reference signal oscillator 25 which oscillates a second reference signal, an output signal of the voltage controlled oscillator 11 and a second reference signal. A mixer 26 that mixes with a second reference signal oscillated by the oscillator 25, a first bandpass filter 27 as a second filter that extracts an addition frequency component from the output of the mixer 26, and a mixer 26.
A second bandpass filter 28 as a second filter for extracting a subtraction frequency component from the output of the, a frequency divider 12 for dividing the subtraction frequency extracted by the second bandpass filter 28, and a first reference frequency. First reference oscillator 1
5 and the output phase of the frequency divider 12 to generate an error voltage, the phase comparator 13 and the first filter for integrating the error voltage of the phase comparator 13 and applying it to the voltage controlled oscillator 11. And a low pass filter 14 as The first bandpass filter 27 is the mixer 4
The second band pass filter 28 is connected to an FM modulator 29 described later.

On the other hand, the modulation signal processing circuit 17 is connected to the FM modulator 29, and the FM modulator 29 is connected to the amplifier 23 for amplifying its output. And
A transmission bandpass filter 24 for removing unnecessary components is connected to the amplifier 23, and the transmission bandpass filter 24 is connected to the antenna 1. The FM modulator 29 includes a double balanced mixer 30 that multiplies the output signal (transmission carrier signal) from the second bandpass filter 28 and the audio signal from the modulation signal processing circuit 17, and a second bandpass filter. The output signal from 28 (transmitted carrier signal) is 9
The phase shifter 31 shifts the phase by 0 ° and the adder 32 synthesizes the output signal (multiplied signal) of the double balanced mixer 30 and the 90 ° phase signal.

Next, the operation of this embodiment will be described.

The antenna 1 receives a radio wave radiated in space, converts it into a high frequency signal and sends it to the reception band pass filter 2. Then, the high-frequency signal has its unnecessary components removed by the bandpass filter 2, is sent to the amplifier 3, and is amplified by the amplifier 3. Then, the high frequency signal amplified by the amplifier 3 is sent to the mixer 4, and the mixer 4 mixes this high frequency signal with the local oscillation signal sent from the synthesizer circuit 34 to obtain a sum or difference frequency component of each signal. To be converted.

Further, the difference frequency component is selected as the first intermediate frequency signal by the intermediate frequency band pass filter 5 and is sent to the mixer 7, and the mixer 7 receives the first intermediate frequency signal and the second local oscillator. The oscillating signal from 6 is mixed and converted into a second intermediate frequency signal. Then, the second intermediate frequency signal is input to the demodulation circuit 8, and the demodulation circuit 8 amplifies and limits the amplitude of the second intermediate frequency signal, and then performs FM detection and sends it to the transmission circuit of the handset 10. Then, the handset 10 converts the voice signal from the demodulation circuit 8 into a voice with a built-in speaker and speaks. At the same time, the built-in microphone picks up the voice and converts it into a voice signal.

The operation of the synthesizer circuit 34 will be described below.

The output signal of the voltage controlled oscillator 11 and the output signal of the second reference signal oscillator 25 are mixed by the mixer 26, and an addition frequency component and a subtraction frequency component having the sum and difference frequencies of these frequencies are generated. To be done. For example, in the case of a mobile device of a cordless telephone, according to the standard of the wireless system, the reception frequency is higher than the transmission frequency, so that the added frequency component selected by the first bandpass filter 27 becomes the local oscillation signal and the second bandpass filter 28 The subtracted frequency component selected in step 2 becomes the transmission carrier signal.

When setting the CH, the data having the division ratio N _T is set from the system controller 9, and the subtraction frequency component serving as the transmission carrier signal is the division ratio N _T.
The frequency is divided by the frequency divider 12. Then, the frequency-divided output signal of the frequency divider 12 and the frequency-divided output signal of the first reference oscillator 15 are phase-compared by the phase comparator 13, and the phase comparator 13
Produces its error signal. Then, the low-pass filter 14 integrates the error signal and applies it to the voltage controlled oscillator 11. Further, since the oscillation frequency of the voltage controlled oscillator 11 varies so as to reduce the phase error, when the first reference frequency is F _{r in} the steady state, the phase error of each signal disappears and the transmission of the synthesizer circuit 34 is eliminated. The carrier signal frequency F _OT is F _OT = N _T · F _r .

If F _{R is} the receiving frequency, F _RL is the receiving local oscillation frequency, F _{OT is} the transmitting frequency, F _O is the second reference frequency, F _{V is the} voltage controlled oscillator frequency, and F ₁ is the receiving intermediate frequency, then F _OT = F _V −F _O F _RL = F _V + F _O F _R = F _RL + F _{1 From} the above, the following relationship is obtained.

F _O = (F _RL −F _OT ) / 2 F _V = (F _RL + F _OT ) / 2 where F _R and F _OT are determined by the communication system standard, and F ₁ is arbitrarily selected. Therefore, F _O and F _V can be determined by determining F ₁ .

In the steady state, since F _OT = N _T · F _r as described above, F _RL = 2F _O + N _T · F _r , and a synthesizer receiver can be realized with one PLL circuit.

Generally, the first reference frequency F _r is made of a stable oscillator in accordance with the communication system standard, but the receiving local oscillation frequency F _RL may be within a range that can be compensated by the function of the receiving circuit. The oscillator is a SAW oscillator,
An inexpensive circuit such as an LC oscillating circuit may be used, and sufficient reception performance can be obtained only by adopting AFC for feeding back the low frequency component of the FM demodulation output signal. Further, stabilization can be realized by setting the first reference oscillator frequency so as to satisfy the formula F _O = M · F _r so that the harmonic component of the first reference frequency oscillator can be used.

Next, the modulation of the transmission carrier signal will be described.

The modulation signal processing circuit 17 is used in the handset 1
The audio signal from 0 is subjected to signal processing such as bandwidth and amplitude limitation, and the processed audio signal is input to the FM modulator 29. Then, the transmission carrier signal from the second bandpass filter 28 is multiplied by the voice signal by the double balanced mixer 30 and input to the adder 32. On the other hand, the transmission carrier signal is phase-shifted by 90 ° by the phase shifter 31 and input to the adder 32. Then, the adder 32 adds the audio signal and the multiplication signal and outputs the result to the amplifier 23. Then, unnecessary signals are removed from the signal amplified by the transmission amplifier 23 by the transmission band pass filter 24, and the signal is radiated into space from the antenna 1.

[0039] In the modulation method in this way, the FM modulation factor m is small narrowband FM modulation, e = Ecos [ωt + msinω m t] = Ecosωt · cos [msinω m t] -Esinωt · sin [ms inω m t] _{= Ecosωt-Emsinωt · sinω m t} = Ecosωt + [cos (ω + ω m) t-sin (ω + ω m) t] / circuit based 2 on the made principle is constituted.

Embodiment 2 FIG. 2 is a block diagram showing another embodiment of the present invention.
As compared with the first embodiment shown in FIG. 1, the input signal of the frequency divider 12 constituting the synthesizer circuit 34 is used as a signal corresponding to the output signal of the voltage controlled oscillator 11 and the output signal of the second reference oscillator, and the harmonics of the first reference oscillator are compared. The wave is selected by the third band pass filter 33, and the mixer 26 mixes the output signal of the voltage controlled oscillator 11 and the output signal of the third band pass filter 33 to generate an addition frequency component and a subtraction frequency component. It's different. First reference signal oscillator 1
5 and the bandpass filter 33 constitute a variable frequency oscillator. As a result, the second reference signal oscillator 2
You don't need 5.

The frequency setting can be determined as in the first embodiment. Since the transmission carrier frequency is F _OT = F _V + F _O = N _T · F _r + F _O , the frequency stability of the second reference oscillator is required to have high performance. In the second embodiment, since the harmonics of the first reference oscillator are used, high transmission frequency stability is ensured.

[0042]

As described above, according to the present invention, the output frequency of the voltage controlled oscillator is divided by the frequency divider, and the first reference frequency is generated by the first reference oscillator. An error voltage is generated by comparing the output phase and the output phase of the frequency divider by a comparator, the error voltage of the phase comparator is integrated by the first filter, and the second reference frequency by the second reference oscillator. The output of the voltage controlled oscillator and the output of the second reference oscillator are mixed by a mixer, and the addition or subtraction frequency component of both outputs from the mixer is extracted by the second filter, and the second filter output Alternatively, since the output of the voltage controlled oscillator is configured to be the input signal of the frequency divider, the addition frequency component and the subtraction frequency component can be used as the local oscillation signal and the transmission carrier signal, and one PLL circuit can be used for transmission and reception. Can be realized sizer circuit, it is possible to reduce the cost, it is possible to IC of the circuit.

Since the local oscillation signal and the transmission carrier signal are produced by mixing the output frequency of the second oscillator and the output frequency of the voltage controlled oscillator, the oscillation frequency of the voltage controlled oscillator is different from that of the transmission carrier signal. Further, there is an effect that a high-quality modulated wave can be obtained without the transmission carrier wave interfering with the voltage controlled oscillator.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a synthesizer receiver according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a synthesizer receiver according to another embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a conventional synthesizer receiver.

[Explanation of symbols]

 11 Voltage Controlled Oscillator 12 Frequency Divider 13 Phase Comparator 14 Low Pass Filter 15 First Reference Oscillator 25 Second Reference Oscillator 26 Mixer 27 First Band Pass Filter 28 Second Band Pass Filter

Claims (5)

[Claims] 1. A voltage controlled oscillator for controlling an oscillation frequency by a voltage, a frequency divider for dividing an output frequency of the voltage controlled oscillator, a first reference oscillator for generating a first reference frequency, and a second reference. A second reference oscillator that generates a frequency; a phase comparator that generates an error voltage by comparing the output phase of the first reference oscillator and the output phase of the frequency divider; and a phase comparator that integrates the error voltage of the phase comparator. One filter, the output signal of the voltage controlled oscillator, and the output signal of the second reference oscillator are mixed, the addition frequency component signal having a frequency component of the sum of the frequencies of both output signals, the difference between the frequencies of both outputs A mixer for outputting a subtraction frequency component signal having a frequency component of, and a second signal for extracting one of the addition frequency component signal or the subtraction frequency component signal from the output signal of the mixer Comprising a filter, a synthesizer receiver, characterized in that the second filter output or voltage controlled oscillator output as the input signal of the divider. 2. A voltage-controlled oscillator for voltage-controlling so as to oscillate an oscillating frequency of 1/2 of a frequency obtained by adding a transmission frequency and a local oscillating frequency, and a frequency divider for dividing an output frequency of the voltage-controlled oscillator. A first reference oscillator that generates a first reference frequency, a second reference oscillator that generates a second reference frequency, and an error voltage by comparing the output phase of the first reference oscillator and the output phase of the frequency divider. A phase comparator for generating the output signal of the voltage controlled oscillator and the output signal of the second reference oscillator, and an addition frequency component signal having a frequency component of the sum of the frequencies of both output signals, and both outputs A mixer that outputs a subtraction frequency component signal having a frequency component of a frequency difference, and one of the addition frequency component signal and the subtraction frequency component signal is extracted from the output signal of the mixer. A synthesizer receiver comprising: a second filter for outputting, and a second filter output or a second voltage controlled oscillator output as an input signal of the frequency divider. 3. A voltage controlled oscillator for controlling an oscillation frequency by voltage, a frequency divider for dividing an output frequency of the voltage controlled oscillator, a frequency obtained by subtracting a transmission frequency from a local oscillation frequency or a local oscillation frequency from a transmission frequency. A second reference oscillator that generates a second reference frequency that is the subtracted frequency, an output signal of the voltage controlled oscillator, and an output signal of the second reference oscillator are mixed, and the frequency component of the sum of the frequencies of both output signals is mixed. And a subtraction frequency component signal having a frequency component of a difference between the frequencies of the two outputs, and a mixer that outputs the addition frequency component signal or the subtraction frequency from the output signal of the mixer. A second filter for extracting either the component signal or one of the signals, and the second filter output or the first voltage controlled oscillator output to the frequency divider input. Synthesizer receiver, characterized in that the items. 4. A voltage controlled oscillator for controlling an oscillation frequency by voltage, a frequency divider for dividing an output frequency of the voltage controlled oscillator, a first reference oscillator for generating a first reference frequency, and a first reference. A second reference oscillator that generates an Nth harmonic of the frequency, an output signal of the voltage controlled oscillator, and an output signal of the second reference oscillator are mixed, and an addition frequency having a frequency component of the sum of the frequencies of both output signals is added. A mixer that outputs a component signal and a subtraction frequency component signal having a frequency component of a difference between the frequencies of both outputs, and from the output signal of the mixer, the addition frequency component signal or the subtraction frequency component signal, A synthesizer receiver comprising a second filter for extracting one of the signals, and the second filter output or the first voltage-controlled oscillator output as the input signal of the frequency divider. Machine. 5. A voltage controlled oscillator for controlling an oscillation frequency by a voltage, a variable frequency oscillator for frequency controlled by an error component of an intermediate frequency, an output signal of the voltage controlled oscillator and an output signal of a second reference oscillator are mixed. A mixer for outputting an addition frequency component signal having a frequency component of the sum of the frequencies of both output signals, and a subtraction frequency component signal having a frequency component of the difference between the frequencies of both outputs, and an output signal of the mixer A second filter for extracting one of the addition frequency component signal and the subtraction frequency component signal from the second filter, the synthesizer receiver.