JP2000196354A - Exciting machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the error of an output level owing to the temp. characteristic of a wave detector by attenuating the output signal of a power synthesizer by means of a temp. variable attenuator having a temp. characteristic for compensating the temp. characteristic of the wave detector. SOLUTION: The output signal of the power synthesizer 13 is attenuated by the temp. variable attenuator 15 having a temp. characteristic for compensating the temp. characteristic of the wave detector 16. A comparator 18 compares the wave detection signal of the wave detector 16 for detecting the output signal of the attenuator 15 with a reference signal which is outputted from a reference signal generator 17 and corresponds to the output frequency of a variable frequency generator 4 and a variable attenuator driver 19 outputs a control signal for eliminating the difference of the comparator 18 to the variable attenuator 2. Thus, the variable attenuator 2 attenuates the output level of a fixed frequency oscillator 1 to output the signal with the desired output level from an output terminal 14. The power synthesizer 13 is constituted without using nonlinear parts so that the level of unwanted wave which becomes high by the use of nonlinear parts is suppressed to be equal to below a desired level.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an exciter used for a test device for evaluating an antenna and capable of transmitting an octave transmission frequency.

[0002]

2. Description of the Related Art FIG. 8 is a block diagram showing the configuration of a conventional exciter, wherein 1 is a fixed frequency oscillator, 2 is a variable attenuator, 3 is a frequency setting controller, 4 is a variable frequency oscillator,
5 is a frequency synthesizer, 6 is a variable band-pass filter, 7 is a variable band-pass filter control driver, 8 is an amplifier, 9 is a first switch, 10 is a switch control driver, 11 is a first low-pass filter, 12 Is a second low-pass filter, 14 is an output terminal, 15 is a detector, 17 is a reference signal generator, 18 is a comparator, 19 is a variable attenuator control driver,
25 is a second switch.

The operation of a conventional exciter will be described with reference to FIG. With respect to the fixed frequency oscillator 1 whose output frequency is f ₁ , the variable frequency oscillator 4 is controlled by the control signal of the frequency setting controller 3.
Is set to f ₂ , the frequency synthesizer 5 generates a signal whose output frequency is f ₀ (f ₀ = f ₁ + f ₂ ). The frequency setting controller 3 outputs a pass band setting control signal corresponding to the output frequency f ₂ of the variable frequency oscillator 4 to the variable band pass filter 6 via the variable band pass filter control driver 7 so that the variable band pass filter 6 suppresses unnecessary waves included in the output signal of the frequency synthesizer 5. The frequency setting controller 3 is a switch control driver 10
Output a switch switching control signal corresponding to the output frequency f ₂ of the variable frequency oscillator 4 to the first switch 9 and the second switch 25 through the first switch 9.
And the second switch 25 select a system that passes through the first low-pass filter 11, and the low-pass filter 11
Undesired waves included in the output signal are suppressed. The comparator 18 is a detector 16 for detecting the output level of the second switch 25.
Is compared with the reference signal output from the reference signal generator 17 and corresponding to the output frequency f ₂ of the variable frequency oscillator 4, and the variable attenuator control driver 19 outputs a control signal for eliminating the difference of the comparator 18. By outputting to the variable attenuator 2,
The variable attenuator 2 attenuates the output level of the fixed frequency oscillator 1 so that a signal having a desired output level is output from the output terminal 14.

[0004] with respect to the fixed frequency oscillator 1 output frequency is f _1, by setting the output frequency of the variable frequency oscillator 4 to f ₁ + 2f ₂ by the control signal of the frequency setting control unit 3, the output frequency by the frequency synthesizer 5 Is 2f ₀ (2f ₀
= F ₁ + f ₁ + 2f ₂ ). The frequency setting controller 3 outputs the output frequency f ₁ + 2f _{2 of the} variable frequency oscillator 4 via the variable band-pass filter control driver 7.
Is output to the variable bandpass filter 6, the variable bandpass filter 6 suppresses unnecessary waves included in the output signal of the frequency synthesizer 5. The frequency setting controller 3 outputs a switch switching control signal corresponding to the output frequency f ₁ + 2f ₂ of the variable frequency oscillator 4 to the first switch 9 and the second switch 25 via the switch control driver 10, The first switch 9 and the second switch 25 are connected to the second low-pass filter 12.
Is selected, and the second low-pass filter 12 suppresses an unnecessary wave included in the output signal of the amplifier 8. The comparator 18 compares a detection signal of the detector 16 for detecting an output level of the second switch 25 with a reference signal output from the reference signal generator 17 and corresponding to the output frequency f ₁ + 2f ₂ of the variable frequency oscillator 4. Compare and control variable attenuator control driver 1
Reference numeral 9 designates a control signal for eliminating the difference of the comparator 18 as a variable attenuator 2
, The variable attenuator 2 attenuates the output level of the fixed frequency oscillator 1 so that a signal having a desired output level is output from the output terminal 14.

[0005]

In this conventional exciter, the variable attenuator control driver outputs a control signal for eliminating the difference of the comparator 18 to the variable attenuator 19, so that the frequency characteristic of the main signal system and the temperature It suppresses an error from the output signal level due to the characteristic. However, when the output level of the second switch 25 is detected by the detector 16, an error occurs in the correspondence between the output level of the second switch 25 and the detection voltage of the detector 16 due to the temperature characteristics of the detector 16. There is a problem that an error between the output level of the output terminal 14 and a desired output level increases.

In addition, the unnecessary wave level of the second switch 25 in which an unnecessary wave is generated due to the use of a non-linear component therein is reduced by the first low-pass filter 11 or the second low-pass filter. If the level of the unnecessary wave suppressed by the filter 12 is higher, the level of the unnecessary wave of the signal output from the output terminal 14 becomes high, and there is a problem that a receiver having the same frequency as the unnecessary wave is interfered.

The present invention has been proposed to solve the problems of such a technique, and has as its object to provide an exciter capable of suppressing an output level error due to a temperature characteristic of a detector.

It is another object of the present invention to provide an exciter capable of suppressing an unnecessary wave level which is increased by using a non-linear component to a desired level or less.

[0009]

An exciter according to a first aspect of the present invention includes a fixed frequency oscillator, a variable attenuator for attenuating the output level of the fixed frequency oscillator, a frequency setting controller,
A variable frequency oscillator whose frequency is set by a control signal of the frequency setting controller; a frequency synthesizer for frequency-synthesizing an output signal of the variable attenuator and an output signal of the variable frequency oscillator; and an output of the frequency synthesizer. A variable band-pass filter for suppressing unnecessary waves included in a signal; and a control signal of the frequency setting controller, and outputting a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band pass filter. A variable band-pass filter control driver, an amplifier for amplifying an output signal of the variable band-pass filter, a switch for selecting a path through which the output signal of the amplifier passes, and a control signal for receiving the control signal of the frequency setting controller. A switch control driver for outputting a switch switching control signal corresponding to a set frequency of a frequency oscillator to the switch. A first low-pass filter for suppressing unnecessary waves included in one output signal of the switch, and a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch. A power combiner that combines an output signal of the first low-pass filter and an output signal of the second low-pass filter, an output terminal that outputs an output signal of the power combiner, Temperature attenuator for attenuating the output signal of the temperature-variable attenuator, a detector for detecting the output level of the temperature-variable attenuator, and a reference corresponding to the set frequency of the variable frequency oscillator receiving the control signal of the frequency setting controller. A reference signal generator for generating a signal; a comparator for comparing a detection signal output from the detector with a reference signal output from the reference signal generator; Decrease It is composed of a variable attenuator control driver for outputting a control signal for setting the amount of attenuation in the vessel.

An exciter according to a second aspect of the present invention provides a fixed frequency oscillator, a variable attenuator for attenuating the output level of the fixed frequency oscillator, a frequency setting controller, and a frequency setting controller that controls the frequency by using a control signal from the frequency setting controller. Is set, a frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable for suppressing unnecessary waves contained in the output signal of the frequency synthesizer. A band-pass filter, a variable band-pass filter control driver that receives a control signal of the frequency setting controller, and outputs a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band-pass filter; An amplifier for amplifying an output signal of the band-pass filter, a switch for selecting a path through which the output signal of the amplifier passes, A switch control driver for receiving a control signal of a wave number setting controller and outputting a switch switching control signal corresponding to a set frequency of the variable frequency oscillator to the switch; and suppressing an unnecessary wave included in one output signal of the switch. A first low-pass filter, a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch, an output signal of the first low-pass filter, and a second low-pass filter. A power combiner for combining an output signal of the band-pass filter, an output terminal for outputting an output signal of the power combiner, a variable temperature attenuator for attenuating an output signal of the power combiner, and a variable temperature attenuator And a reference signal generator for receiving a control signal of the frequency setting controller and generating a reference signal corresponding to a set frequency of the variable frequency oscillator. A comparator for comparing a detection signal output from the detector with a reference signal output from the reference signal generator, and receiving an output signal of the comparator and setting an attenuation amount in the variable attenuator. And a variable attenuator control driver for outputting a control signal.

Further, an exciter according to a third aspect of the present invention provides a fixed frequency oscillator, a variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, and a frequency setting controller that controls a frequency by using a control signal of the frequency setting controller. Is set, a frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable for suppressing unnecessary waves contained in the output signal of the frequency synthesizer. A band-pass filter, a variable band-pass filter control driver that receives a control signal of the frequency setting controller, and outputs a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band-pass filter; An amplifier for amplifying an output signal of the band-pass filter, a switch for selecting a path through which the output signal of the amplifier passes, A switch control driver for receiving a control signal of a wave number setting controller and outputting a switch switching control signal corresponding to a set frequency of the variable frequency oscillator to the switch; and suppressing an unnecessary wave included in one output signal of the switch. A first low-pass filter, a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch, an output signal of the first low-pass filter, and a second low-pass filter. A power combiner that combines an output signal of the bandpass filter, an output terminal that outputs an output signal of the power combiner, a variable temperature amplifier that amplifies an output signal of the power combiner, and an output of the variable temperature amplifier. A detector for detecting a level, and a reference signal generator for receiving a control signal from the frequency setting controller and generating a reference signal corresponding to a set frequency of the variable frequency oscillator. A comparator for comparing a detection signal output from the detector with a reference signal output from the reference signal generator, and receiving an output signal of the comparator and setting an attenuation amount in the variable attenuator. And a variable attenuator control driver for outputting a control signal.

Further, an exciter according to a fourth aspect of the present invention provides a fixed frequency oscillator, a variable attenuator for attenuating the output level of the fixed frequency oscillator, a frequency setting controller, and a frequency setting control signal from the frequency setting controller. Is set, a frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable for suppressing unnecessary waves contained in the output signal of the frequency synthesizer. A band-pass filter, a variable band-pass filter control driver that receives a control signal of the frequency setting controller, and outputs a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band-pass filter; An amplifier for amplifying an output signal of the band-pass filter, a switch for selecting a path through which the output signal of the amplifier passes, A switch control driver for receiving a control signal of a wave number setting controller and outputting a switch switching control signal corresponding to a set frequency of the variable frequency oscillator to the switch; and suppressing an unnecessary wave included in one output signal of the switch. A first low-pass filter, a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch, an output signal of the first low-pass filter, and a second low-pass filter. A power combiner that combines the output signal of the bandpass filter, an output terminal that outputs the output signal of the power combiner, a variable amplifier that amplifies the output signal of the power combiner, and an amplification amount of the variable amplifier. A temperature compensation control driver, a detector for detecting the output level of the variable amplifier, and a control signal for receiving the control signal from the frequency setting controller. A reference signal generator for generating a reference signal corresponding to a frequency, a comparator for comparing a detection signal output from the detector with a reference signal output from the reference signal generator, and an output signal of the comparator And a variable attenuator control driver for outputting a control signal for setting the amount of attenuation to the variable attenuator.

An exciter according to a fifth aspect of the present invention provides a fixed frequency oscillator, a variable attenuator for attenuating the output level of the fixed frequency oscillator, a frequency setting controller, and a frequency setting controller that controls the frequency by using a control signal from the frequency setting controller. Is set, a frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable for suppressing unnecessary waves contained in the output signal of the frequency synthesizer. A band-pass filter, a variable band-pass filter control driver that receives a control signal of the frequency setting controller, and outputs a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band-pass filter; An amplifier for amplifying an output signal of the band-pass filter, a switch for selecting a path through which the output signal of the amplifier passes, A switch control driver for receiving a control signal of a wave number setting controller and outputting a switch switching control signal corresponding to a set frequency of the variable frequency oscillator to the switch; and suppressing an unnecessary wave included in one output signal of the switch. A first low-pass filter, a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch, an output signal of the first low-pass filter, and a second low-pass filter. A power combiner that combines an output signal of the bandpass filter, an output terminal that outputs an output signal of the power combiner, a detector that detects an output level of the power combiner, and a detector that detects a detection signal of the detector. A temperature compensation circuit for performing temperature compensation, a reference signal generator that receives a control signal of the frequency setting controller, and generates a reference signal corresponding to a set frequency of the variable frequency oscillator; A comparator for comparing an output signal output from the temperature compensation circuit with a reference signal output from the reference signal generator; and a control for receiving an output signal of the comparator and setting an attenuation amount in the variable attenuator. And a variable attenuator control driver for outputting a signal.

An exciter according to a sixth aspect of the present invention provides a fixed frequency oscillator, a variable attenuator for attenuating the output level of the fixed frequency oscillator, a frequency setting controller, and a frequency setting controller which controls the frequency by using a control signal of the frequency setting controller. Is set, a frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable for suppressing unnecessary waves contained in the output signal of the frequency synthesizer. A band-pass filter, a variable band-pass filter control driver that receives a control signal of the frequency setting controller, and outputs a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band-pass filter; An amplifier for amplifying an output signal of the band-pass filter, a switch for selecting a path through which the output signal of the amplifier passes, A switch control driver for receiving a control signal of a wave number setting controller and outputting a switch switching control signal corresponding to a set frequency of the variable frequency oscillator to the switch; and suppressing an unnecessary wave included in one output signal of the switch. A first low-pass filter, a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch, an output signal of the first low-pass filter, and a second low-pass filter. A power combiner that combines an output signal of the bandpass filter, an output terminal that outputs an output signal of the power combiner, a detector that detects an output level of the power combiner, and control of the frequency setting controller. A reference signal generator for receiving a signal and generating a reference signal corresponding to a set frequency of the variable frequency oscillator; a detection signal output from the detector and the reference signal generation; A variable attenuator control driver for receiving a signal output from the comparator and outputting a control signal for setting an amount of attenuation of the variable attenuator; And a temperature compensation circuit that compensates the temperature of the output signal of the driver.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 is a block diagram showing a configuration of an exciter according to a first embodiment of the present invention. In FIG. 13 is a power combiner, and 15 is a variable temperature attenuator. FIG. 2 is a diagram illustrating a configuration of the power combiner 13 that does not use a nonlinear component, where In1 is a first input terminal,
In2 is a second input terminal, Out is an output terminal, M is a microstrip line, and R is an isolation resistor.

When the output frequency of the variable frequency oscillator 4 is set to f ₂ by the control signal of the frequency setting controller 3 for the fixed frequency oscillator ₁ having the output frequency f ₁ , the output frequency is set to f ₂ by the frequency synthesizer 5. ₀ (f ₀ = f ₁ + f
₂ ) A signal is generated. The frequency setting controller 3 outputs a pass band setting control signal corresponding to the output frequency f ₂ of the variable frequency oscillator 4 to the variable band pass filter 6 via the variable band pass filter control driver 7 so that the variable band pass filter 6 suppresses unnecessary waves included in the output signal of the frequency synthesizer 5. The frequency setting controller 3 outputs a switch switching control signal corresponding to the output frequency f ₂ of the variable frequency oscillator 4 to the switch 9 via the switch control driver 10, so that the switch 9 becomes the first low-pass filter 11. Is selected, and the low-pass filter 11 suppresses unnecessary waves included in the output signal of the amplifier 8. The output signal of the power combiner 13 is attenuated by the variable temperature attenuator 15 having a temperature characteristic that compensates for the temperature characteristic of the detector 16. The comparator 18 detects a detection signal of the detector 16 for detecting an output signal of the variable temperature attenuator 15 and a reference signal generator 17.
Is compared with a reference signal corresponding to the output frequency f ₂ of the variable frequency oscillator 4 and the variable attenuator control driver 1
Reference numeral 9 designates a control signal for eliminating the difference of the comparator 18 as a variable attenuator 2
, The variable attenuator 2 attenuates the output level of the fixed frequency oscillator 1 so that a signal having a desired output level is output from the output terminal 14.

When the output frequency of the variable frequency oscillator 4 is set to f ₁ + 2f ₂ by the control signal of the frequency setting controller 3 for the fixed frequency oscillator 1 whose output frequency is f ₁ , the output frequency is set by the frequency synthesizer 5. Is 2f ₀ (2f ₀
= F ₁ + f ₁ + 2f ₂ ). The frequency setting controller 3 outputs the output frequency f ₁ + 2f _{2 of the} variable frequency oscillator 4 via the variable band-pass filter control driver 7.
Is output to the variable bandpass filter 6, the variable bandpass filter 6 suppresses unnecessary waves included in the output signal of the frequency synthesizer 5. The frequency setting controller 3 outputs a switch switching control signal corresponding to the output frequency f ₁ + 2f ₂ of the variable frequency oscillator 4 to the switch 9 via the switch control driver 10, so that the switch 9 performs the second low-pass operation. A system that passes through the filter 12 is selected, and the second low-pass filter 12 suppresses unnecessary waves included in the output signal of the amplifier 8. The output signal of the power combiner 13 is attenuated by the variable temperature attenuator 15 having a temperature characteristic that compensates for the temperature characteristic of the detector 16. The comparator 18 compares a detection signal of the detector 16 for detecting an output signal of the variable temperature attenuator 15 with a reference signal output from the reference signal generator 17 and corresponding to the output frequency f ₁ + 2f ₂ of the variable frequency oscillator 4. Compare and control variable attenuator control driver 1
Reference numeral 9 designates a control signal for eliminating the difference of the comparator 18 as a variable attenuator 2
, The variable attenuator 2 attenuates the output level of the fixed frequency oscillator 1 so that a signal having a desired output level is output from the output terminal 14.

The power combiner 13 does not use the non-linear component shown in FIG. 2, and a signal input from the first input terminal In1 or the second input terminal In2 is formed on the dielectric substrate Y by a micro-power. Transmitting the stripline M,
Part of the signal is output from the output terminal Out, and the remaining signal is absorbed by the isolation resistor M.

Embodiment 2 FIG. 3 is a block diagram showing the configuration of an exciter according to a second embodiment of the present invention. In FIG. 13 is a power combiner, 20 is a second variable attenuator,
21 is a temperature compensation control driver.

In the first embodiment, the variable temperature attenuator 1
5, the temperature characteristic of the detector 16 is compensated. The temperature characteristic of the detector 16 is compensated for by the second variable attenuator 20 and the temperature compensation control driver 21 having the temperature characteristic of compensating the temperature characteristic of the detector 16. To compensate. In this embodiment, the same effect as in the first embodiment can be expected.

Embodiment 3 FIG. 4 is a block diagram showing a configuration of an exciter according to a third embodiment of the present invention. In FIG. 13 is a power combiner, 22 is a variable temperature amplifier.

In the first embodiment, the temperature variable attenuator 1
5, the temperature characteristic of the detector 16 is compensated.
The temperature characteristic of the detector 16 is compensated for by the temperature variable amplifier 22 having the temperature characteristic for compensating the temperature characteristic of No. 6.
In this embodiment, the same effect as in the first embodiment can be expected.

Embodiment 4 FIG. 5 is a block diagram showing a configuration of an exciter according to a fourth embodiment of the present invention. In FIG. 13 is a power combiner, 21 is a temperature compensation control driver, and 23 is a variable amplifier.

In the first embodiment, the variable temperature attenuator 1
5, the temperature characteristic of the detector 16 is compensated for, but the temperature characteristic of the detector 16 is compensated for by the variable attenuator 23 and the temperature compensation control driver 21 having the temperature characteristic of compensating the temperature characteristic of the detector 16. It is. Embodiment 1 in the present embodiment
The same effect can be expected.

Embodiment 5 FIG. FIG. 6 is a block diagram showing the configuration of an exciter according to a fifth embodiment of the present invention. In FIG. 13 is a power combiner, and 24 is a temperature compensation circuit.

In the first embodiment, the temperature variable attenuator 1
5, the temperature characteristic of the detector 16 is compensated.
The temperature characteristic of the detector 16 is compensated by a temperature compensating circuit 24 having a temperature characteristic for compensating the temperature characteristic of No. 6. In this embodiment, the same effect as in the first embodiment can be expected.

Embodiment 6 FIG. FIG. 7 is a block diagram showing the configuration of an exciter according to a sixth embodiment of the present invention. In FIG. 13 is a power combiner, and 24 is a temperature compensation circuit.

In the fifth embodiment, the temperature compensation circuit 24
Is provided between the detector 16 and the comparator 18, but the temperature compensation circuit 24 is provided between the variable attenuator control driver 19 and the variable attenuator 2. In this embodiment, the same effect as in the fifth embodiment can be expected.

In the above-described embodiment, the output frequency output from the output terminal is set to f ₀ or 2f _0. However, an arbitrary frequency is distributed to two or more systems, and two or more low-pass filters are used. Even when the unnecessary waves are suppressed, the effect of the present invention can be obtained similarly.

[0030]

According to the first aspect of the present invention, the output signal of the power combiner is attenuated by the variable temperature attenuator having a temperature characteristic for compensating for the temperature characteristic of the detector, so that the output level based on the temperature characteristic of the detector is obtained. Can be suppressed.

Further, the system that passes through the first low-pass filter and the system that passes through the second low-pass filter are combined into a single system using a power combiner that does not use nonlinear components internally, so that the output can be reduced. The unnecessary wave level of the unnecessary wave output from the terminal can be suppressed to the unnecessary wave level suppressed by the first low-pass filter or the second low-pass filter.

According to the second aspect, the output signal of the power combiner is attenuated by the second variable attenuator having the temperature compensation control driver having the temperature characteristic for compensating the temperature characteristic of the detector, thereby detecting the signal. The error of the output level due to the temperature characteristic of the vessel can be suppressed.

Also, the system that passes through the first low-pass filter and the system that passes through the second low-pass filter are combined into one system by using a power combiner that does not use nonlinear components internally, so that the output can be reduced. The unnecessary wave level of the unnecessary wave output from the terminal can be suppressed to the unnecessary wave level suppressed by the first low-pass filter or the second low-pass filter.

According to the third aspect, the output signal of the power combiner is amplified by the temperature variable amplifier having the temperature characteristic for compensating the temperature characteristic of the detector, so that the error of the output level due to the temperature characteristic of the detector is reduced. Can be suppressed.

Further, the system that passes through the first low-pass filter and the system that passes through the second low-pass filter are combined into one system using a power combiner that does not use nonlinear components internally, so that the output is reduced. The unnecessary wave level of the unnecessary wave output from the terminal can be suppressed to the unnecessary wave level suppressed by the first low-pass filter or the second low-pass filter.

According to the fourth aspect, the output signal of the power combiner is amplified by the variable amplifier having the temperature compensation control driver having the temperature characteristic for compensating the temperature characteristic of the detector, thereby obtaining the temperature characteristic of the detector. Can suppress the error of the output level.

Further, the system that passes through the first low-pass filter and the system that passes through the second low-pass filter are combined into a single system using a power combiner that does not use nonlinear components internally, so that the output is reduced. The unnecessary wave level of the unnecessary wave output from the terminal can be suppressed to the unnecessary wave level suppressed by the first low-pass filter or the second low-pass filter.

According to the fifth aspect, the detection signal of the detector is compensated by the temperature compensation circuit having the temperature characteristic for compensating the temperature characteristic of the detector, thereby suppressing an error in the output level due to the temperature characteristic of the detector. can do.

Further, the system that passes through the first low-pass filter and the system that passes through the second low-pass filter are combined into one system by using a power combiner that does not use nonlinear components internally, so that the output is reduced. The unnecessary wave level of the unnecessary wave output from the terminal can be suppressed to the unnecessary wave level suppressed by the first low-pass filter or the second low-pass filter.

According to the sixth aspect, the control signal of the variable attenuator control driver is compensated by the temperature compensating circuit having the temperature characteristic for compensating the temperature characteristic of the detector. Errors can be suppressed.

Further, the system that passes through the first low-pass filter and the system that passes through the second low-pass filter are combined into a single system using a power combiner that does not use nonlinear components internally, so that the output is reduced. The unnecessary wave level of the unnecessary wave output from the terminal can be suppressed to the unnecessary wave level suppressed by the first low-pass filter or the second low-pass filter.

[Brief description of the drawings]

FIG. 1 is a diagram showing Embodiment 1 of an exciter according to the present invention.

FIG. 2 is a diagram illustrating a configuration of a power combiner in FIG. 1;

FIG. 3 is a diagram showing Embodiment 2 of the exciter according to the present invention.

FIG. 4 is a diagram showing Embodiment 3 of the exciter according to the present invention.

FIG. 5 is a diagram showing a fourth embodiment of the exciter according to the present invention.

FIG. 6 is a diagram showing Embodiment 5 of the exciter according to the present invention.

FIG. 7 is a diagram showing Embodiment 6 of the exciter according to the present invention.

FIG. 8 is a view showing a conventional exciter.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 fixed frequency oscillator, 2 first variable attenuator, 3 frequency setting controller, 4 variable frequency oscillator, 5 frequency synthesizer, 6 variable bandpass filter, 7 variable bandpass filter control driver, 8 amplifier, 9 first switch,
REFERENCE SIGNS LIST 10 switch control driver, 11 first low-pass filter, 12 second low-pass filter, 13 power combiner, 14 output terminal, 15 variable temperature attenuator, 16
Detector, 17 reference signal generator, 18 comparator, 19
Variable attenuator control driver, 20 second variable attenuator, 21
Temperature compensation control driver, 22 Variable temperature amplifier, 23
Variable amplifier, 24 temperature compensation circuit, 25 second switch, In1 first input terminal, In2 second input terminal, M microstrip line, Out output terminal,
R Isolation resistor, Y dielectric substrate.

Claims (6)

[Claims] 1. A fixed frequency oscillator, a variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, a variable frequency oscillator whose frequency is set by a control signal of the frequency setting controller, A frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable bandpass filter for suppressing unnecessary waves included in an output signal of the frequency synthesizer,
A variable bandpass filter control driver that receives a control signal of the frequency setting controller and outputs a passband setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable bandpass filter; and an output of the variable bandpass filter. An amplifier for amplifying a signal, a switch for selecting a path through which an output signal of the amplifier passes, and a switch switching control signal corresponding to a set frequency of the variable frequency oscillator receiving a control signal of the frequency setting controller. , A first low-pass filter for suppressing unnecessary waves contained in one output signal of the switch, and a second low-pass filter for suppressing unnecessary waves contained in the other output signal of the switch. A low-pass filter; an output signal of the first low-pass filter; and an output signal of the second low-pass filter. , An output terminal for outputting an output signal of the power combiner, a variable temperature attenuator for attenuating the output signal of the power combiner, and detecting an output level of the variable temperature attenuator. A detector, a reference signal generator that receives a control signal of the frequency setting controller and generates a reference signal corresponding to a set frequency of the variable frequency oscillator, a detection signal output from the detector, and the reference signal generation And a variable attenuator control driver that receives the output signal of the comparator and outputs a control signal for setting an amount of attenuation to the variable attenuator. Characteristic exciter. 2. A fixed frequency oscillator, a first variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, and a variable frequency whose frequency is set by a control signal of the frequency setting controller. An oscillator, a frequency synthesizer for frequency-synthesizing an output signal of the first variable attenuator and an output signal of the variable frequency oscillator, and a variable bandpass filter for suppressing unnecessary waves included in an output signal of the frequency synthesizer Receiving a control signal of the frequency setting controller,
A variable bandpass filter control driver for outputting a passband setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable bandpass filter; an amplifier for amplifying an output signal of the variable bandpass filter; and an output of the amplifier. A switch that selects a path through which a signal passes, a switch control driver that receives a control signal of the frequency setting controller, and outputs a switch switching control signal corresponding to a set frequency of the variable frequency oscillator to the switch; A first low-pass filter for suppressing unnecessary waves included in one output signal, a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch, and the first low-pass filter; A power combiner for combining an output signal of the band-pass filter and an output signal of the second low-pass filter; An output terminal for outputting an output signal of the power combiner, a second variable attenuator for attenuating the output signal of the power combiner, a temperature compensation control driver for controlling an amount of attenuation of the second variable attenuator, A detector for detecting an output level of the variable attenuator, a reference signal generator for receiving a control signal of the frequency setting controller and generating a reference signal corresponding to a set frequency of the variable frequency oscillator, and the detector A comparator for comparing a detection signal output from the comparator with a reference signal output from the reference signal generator, and a control signal for receiving an output signal of the comparator and setting an attenuation in the first variable attenuator An exciter comprising a variable attenuator control driver that outputs a signal. 3. A fixed frequency oscillator, a variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, a variable frequency oscillator whose frequency is set by a control signal of the frequency setting controller, A frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable bandpass filter for suppressing unnecessary waves included in an output signal of the frequency synthesizer,
A variable bandpass filter control driver that receives a control signal of the frequency setting controller and outputs a passband setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable bandpass filter; and an output of the variable bandpass filter. An amplifier for amplifying a signal, a switch for selecting a path through which an output signal of the amplifier passes, and a switch switching control signal corresponding to a set frequency of the variable frequency oscillator receiving a control signal of the frequency setting controller. , A first low-pass filter for suppressing unnecessary waves contained in one output signal of the switch, and a second low-pass filter for suppressing unnecessary waves contained in the other output signal of the switch. A low-pass filter; an output signal of the first low-pass filter; and an output signal of the second low-pass filter. , An output terminal for outputting an output signal of the power combiner, a variable temperature amplifier for amplifying the output signal of the power combiner, and a detector for detecting an output level of the variable temperature amplifier A reference signal generator that receives a control signal of the frequency setting controller and generates a reference signal corresponding to a set frequency of the variable frequency oscillator; and a detection signal output from the detector and the reference signal generator. A comparator for comparing the output signal with a reference signal, and a variable attenuator control driver for receiving a signal output from the comparator and outputting a control signal for setting an amount of attenuation to the variable attenuator. Exciter to do. 4. A fixed frequency oscillator, a variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, a variable frequency oscillator whose frequency is set by a control signal of the frequency setting controller, A frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable bandpass filter for suppressing unnecessary waves included in an output signal of the frequency synthesizer,
A variable bandpass filter control driver that receives a control signal of the frequency setting controller and outputs a passband setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable bandpass filter; and an output of the variable bandpass filter. An amplifier for amplifying a signal, a switch for selecting a path through which an output signal of the amplifier passes, and a switch switching control signal corresponding to a set frequency of the variable frequency oscillator receiving a control signal of the frequency setting controller. , A first low-pass filter for suppressing unnecessary waves contained in one output signal of the switch, and a second low-pass filter for suppressing unnecessary waves contained in the other output signal of the switch. A low-pass filter; an output signal of the first low-pass filter; and an output signal of the second low-pass filter. , An output terminal for outputting an output signal of the power combiner, a variable temperature amplifier for amplifying the output signal of the power combiner, and a temperature compensation for controlling an amplification amount of the variable temperature amplifier. A control driver, a detector for detecting an output level of the variable amplifier,
A reference signal generator that receives a control signal of the frequency setting controller and generates a reference signal corresponding to a set frequency of the variable frequency oscillator, a detection signal output from the detector and an output from the reference signal generator. And a variable attenuator control driver for receiving a signal output from the comparator and outputting a control signal for setting an amount of attenuation to the variable attenuator. Machine. 5. A fixed frequency oscillator, a variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, a variable frequency oscillator whose frequency is set by a control signal of the frequency setting controller, A frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable bandpass filter for suppressing unnecessary waves included in an output signal of the frequency synthesizer,
A variable bandpass filter control driver that receives a control signal of the frequency setting controller and outputs a passband setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable bandpass filter; and an output of the variable bandpass filter. An amplifier for amplifying a signal, a switch for selecting a path through which an output signal of the amplifier passes, and a switch switching control signal corresponding to a set frequency of the variable frequency oscillator receiving a control signal of the frequency setting controller. , A first low-pass filter for suppressing unnecessary waves included in one output signal of the switch, and a second low-pass filter for suppressing unnecessary waves included in the other output signal of the switch. A low-pass filter; an output signal of the first low-pass filter; and an output signal of the second low-pass filter. , An output terminal for outputting an output signal of the power combiner, a detector for detecting an output level of the power combiner, and a temperature compensation circuit for temperature-compensating the detected signal of the detector. A reference signal generator that receives a control signal of the frequency setting controller and generates a reference signal corresponding to a set frequency of the variable frequency oscillator; an output signal output from the temperature compensation circuit; and the reference signal generator And a variable attenuator control driver that receives the output signal of the comparator and outputs a control signal for setting the amount of attenuation to the variable attenuator. And exciter. 6. A fixed frequency oscillator, a variable attenuator for attenuating an output level of the fixed frequency oscillator, a frequency setting controller, a variable frequency oscillator whose frequency is set by a control signal of the frequency setting controller, A frequency synthesizer for frequency-synthesizing the output signal of the variable attenuator and the output signal of the variable frequency oscillator, and a variable bandpass filter for suppressing unnecessary waves included in an output signal of the frequency synthesizer,
A variable band pass filter control driver for receiving a control signal of the frequency setting controller and outputting a pass band setting control signal corresponding to a set frequency of the variable frequency oscillator to the variable band pass filter, and an output of the variable band pass filter An amplifier for amplifying a signal, a switch for selecting a path through which an output signal of the amplifier passes, and a switch switching control signal corresponding to a set frequency of the variable frequency oscillator receiving a control signal of the frequency setting controller. , A first low-pass filter for suppressing unnecessary waves contained in one output signal of the switch, and a second low-pass filter for suppressing unnecessary waves contained in the other output signal of the switch. A low-pass filter; an output signal of the first low-pass filter; and an output signal of the second low-pass filter. A power combiner for synthesizing the power combiner, an output terminal for outputting an output signal of the power combiner, a detector for detecting an output level of the power combiner, and a control signal of the frequency setting controller for receiving the variable signal. A reference signal generator that generates a reference signal corresponding to a set frequency of a frequency oscillator, a comparator that compares a detection signal output from the detector with a reference signal output from the reference signal generator,
A variable attenuator control driver for receiving the output signal of the comparator and outputting a control signal for setting the amount of attenuation of the variable attenuator; a temperature compensation circuit for temperature-compensating the output signal of the variable attenuator control driver; An exciter wherein an output signal of a temperature compensation circuit is connected to the variable attenuator.