JP2000323923A - Dielectric resonator control oscillator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily realize the wide band property of a resonance frequency. SOLUTION: A main dielectric resonator 64 and an auxiliary dielectric resonator 62 are installed in faces to which two parallel sectional plates 57 and 58 fitted to a rotary shaft 59 are confronted and therefore the dielectric resonator of duplex structure is constituted. The sectorial plates 57 and 58 are incorporated and they can freely be turned with the rotary shaft 59 as a center. A micro strip line is arranged along an arc form that the main dielectric resonator 64 draws.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a dielectric resonator controlled oscillator, and more particularly to a dielectric resonator controlled oscillator used as a local oscillation source of a microwave radio communication system.

[0002]

2. Description of the Related Art Conventionally, a dielectric resonator controlled oscillator of this kind has been used as an oscillator of a small and high-performance microwave integrated circuit due to the development of a dielectric material having a low temperature dependence of a dielectric constant and a low loss. ing.

FIG. 5 shows an outline of a configuration of a conventionally proposed dielectric resonator controlled oscillator. The dielectric resonator control oscillator includes a container 10 having an opening on an upper portion, and a dielectric substrate 11 is disposed on a bottom surface in the container 10. On the upper surface of the dielectric substrate 11, a microstrip line 12 is formed. Further, on the dielectric substrate 11, a terminating resistor 13 and a field effect transistor (not shown) are provided. The terminating resistor 13 is connected to one end of the microstrip line 12, and the field-effect transistor is connected to the other end of the microstrip line 12. The opening of the container 10 facing the dielectric substrate 11 provided on the bottom surface of the container 10 has a cover member 14.
It is covered by. The cover member 14 has a through hole at a predetermined position, and a male screw member 16 having a male screw part 15 formed on the outer periphery is inserted. A female screw member 17 having a female screw portion formed on the inner peripheral portion is fixedly provided on the upper surface of the lid member 14, and is screwed with the male screw member 16. One end of an arm member 18 is attached to a male screw member 16 penetrating the lower surface of the lid member 14. The dielectric resonator 19 attached to the other end of the arm member 18
However, a circular arc having a predetermined radius is drawn around a hole provided in the lid member 14 and is configured to be rotatable.

Therefore, the microstrip line 12 disposed on the above-described dielectric substrate 10 is provided with an arc-shaped portion along the rotation locus of the dielectric resonator 19. The dielectric resonator 19 rotates a position close to the microstrip line 12 so as to be magnetically coupled to the microstrip line 12 along the rotation locus. Thereby, while always keeping the distance between the dielectric resonator 19 and the microstrip line 12 constant,
The distance on the microstrip line 12 between the field effect transistor connected to the other end of the microstrip line 12 and the dielectric resonator 19 can be adjusted (adjustment 20). Further, by rotating the female screw member 17, the male screw member 16 screwed with the female screw member 17 can be moved up and down (adjustment 21). Thus, the degree of magnetic field coupling can be adjusted by changing the distance between the dielectric substrate 19 and the microstrip 12. The dielectric resonator control oscillator having such a configuration can finely adjust the position of the dielectric resonator, and can easily adjust it to a desired oscillation phase condition.

A technique relating to such a dielectric resonator controlled oscillator is disclosed, for example, in Japanese Patent Application Laid-Open No. Hei 4-25204, "Microwave Oscillator with Position Adjustment Mechanism for Dielectric Resonator".

[0006] Of the dielectric resonator controlled oscillators proposed in the past as described above, the dielectric resonator controlled oscillator using a TE01δ mode dielectric resonator is particularly applied to a microwave band oscillator. It has excellent phase noise characteristics as a local oscillation source in communication systems. By the way, the oscillation condition in the dielectric resonator controlled oscillator needs to satisfy predetermined amplitude condition and phase condition. In the following, FIG.
This oscillation condition will be described with reference to FIGS.

FIG. 6 schematically shows the configuration of an equivalent circuit of a microwave band oscillator using a conventional TE01δ mode dielectric resonator. This equivalent circuit is divided by an active element side terminal 25 and a resonator side terminal 26, and each impedance is equivalently represented. That is, in the active element side terminal 25, the active element side equivalent circuit 27 is equivalently connected to the active element side terminal 25 by an active element 28 such as a field effect transistor having one end connected to the other end and the other end grounded. Impedance can be represented. In the resonator-side terminal 26, the resonator-side equivalent circuit 29 is equivalently equivalent to the resonator-side impedance by microstrip lines 30 and 31 having one end connected to the resonator-side terminal 26 and the other end grounded. Can be represented. Here, the microstrip line is divided into a microstrip line 30 as an impedance conversion line and a microstrip line 31 as a simple signal transmission path. Further, the length of the adjacent portion where the microstrip line 30 and the dielectric resonator 32 are magnetically coupled is d.

FIG. 7 shows the outline of the configuration of the equivalent circuit of the magnetic field coupling portion and the dielectric resonator of the equivalent circuit shown in FIG. The same parts as those of the equivalent circuit shown in FIG. 6 are denoted by the same reference numerals, and description thereof will be omitted.
That is, in this equivalent circuit, the magnetic field coupling between the microstrip line 30 and the dielectric resonator 32 shown in FIG.
It is equivalently represented by a transformer 33. Also,
The dielectric resonator 32 is equivalently represented by a parallel resonance circuit 34. That is, this indicates that the microstrip line 30 and the parallel resonance circuit 34 are coupled via the transformer 33. The parallel resonance circuit 34
A resistance element 35, an inductance element 36, and a capacitance element 37 are connected in parallel with the transformer 33, respectively.
Transformer 33, of the microstrip line 30, is inserted between the micro strip line 30 ₁ of the portion contributing to magnetic coupling between the dielectric resonator 32, a microstrip line 30 ₂ as part which does not contribute .

FIG. 8 shows the equivalent circuit shown in FIG. 7 in which the transformer 33 and the parallel resonance circuit 34 are equivalently represented by another parallel resonance circuit. The same parts as those of the equivalent circuit shown in FIG. 6 and FIG. That is, this equivalent circuit has one end connected to the resonator-side terminal 2.
The microstrip line 30 ₁ of the other end contributes to the magnetic coupling between the dielectric resonator 32 6 to be connected, is grounded via a parallel resonant circuit 38. That is, between the other end and the ground potential of the micro-strip line 30 _1, the resistance element 39, the inductance element 40 and the capacitor 4
1 are connected in parallel to each other.

As conditions for the oscillator represented by the equivalent circuit shown in FIG. 8 to oscillate, it is necessary to satisfy predetermined amplitude conditions and phase conditions. This is because in the active element-side equivalent circuit 27 and the resonator-side equivalent circuit 29, the resonator-side loss is smaller than the active element-side gain, and the resonator-side reactance is conjugate to the active element-side reactance. It means that it is necessary to satisfy such conditions. Here, the real part of each of the impedances on the active element side and the resonator side is Ra and Rr, and
When the imaginary parts are Xa and Xr, each impedance can be represented as follows.

Active element side impedance: Za = −Ra + jXa (1) Resonator side impedance: Zr = Rr + jXr (2)

From the impedance expressed as described above, the above-described amplitude condition and phase condition for oscillation can be expressed as follows.

Amplitude condition: Ra> Rr (3) Phase condition: Xa = −Xr (4)

[0014] As described above, the magnetic field coupling of the dielectric resonator and the microstrip line is finally table as a series circuit of the microstrip line 30 ₁ of the parallel resonant circuit 38 and the impedance converter shown in FIG. 8 Have been. Here, the amplitude condition represented by the equation (3) depends on the characteristics of the field effect transistor constituting the active element 28. On the other hand, the phase condition indicated by equation (4), the distance of the microstrip line from active elements 28 to the dielectric resonator, i.e. by adjusting the contributing bond length d to the magnetic coupling of the microstrip lines 30 ₁ Can be satisfied.

As a technique relating to a dielectric resonator controlled oscillator, Japanese Patent Application Laid-Open No. 4-162802, entitled "Band Reflection Oscillator", includes a main dielectric resonator provided on the bottom surface of a container having an opening at the top. The sub-dielectric resonator is provided at one end of the movement adjusting member provided on the lid member covering the opening of the container, which is the surface facing the bottom surface of the container.
Further, the screw portion does not protrude outside the container by changing the distance between the main dielectric resonator and the sub-dielectric resonator by rotation of the male screw portion and the female screw portion screwed to the inner surface of the movement adjusting member. Such a technique is disclosed.

[0016]

SUMMARY OF THE INVENTION As a dielectric resonator control oscillator, a main dielectric resonator and a sub dielectric resonator each having a resonance frequency are provided, and the resonance frequency is made variable by changing the distance between each other. There is something that can be done. However, as proposed in the prior art,
Even if the magnetic field coupling length on the microstrip line is made variable as disclosed in Japanese Patent Application Laid-Open No. 204-204, at the same time, the distance between each other is changed as disclosed in Japanese Patent Application Laid-Open No. 4-162802. It is not easy.

Further, in such a dielectric resonator having a double structure, there is a problem that a wide band of a resonance frequency cannot be particularly secured. This is because once the position of the main dielectric resonator is fixed in the oscillator, if the resonance frequency is changed by changing the coupling distance with the sub-dielectric resonator, the above-mentioned (3), ( There is a problem that the oscillation condition of the expression 4) cannot be satisfied, and it has not been possible to easily realize a wide band of the oscillation frequency.
As described above, in the dielectric resonator control oscillator having the conventionally proposed configuration, the adjustment of the resonance frequency and the adjustment of the magnetic field coupling length on the microstrip line cannot be easily adjusted. Was very difficult to achieve.

An object of the present invention is to provide a dielectric resonator controlled oscillator that can easily realize a wide band of oscillation frequency.

[0019]

According to the first aspect of the present invention, there are provided (a) first and second flat plates which are arranged at a predetermined interval in parallel with each other, and (b) these first and second flat plates.
Holding means for rotatably holding the flat plates around these predetermined positions along parallel surfaces of these flat plates,
(C) first and second dielectric resonators mounted on opposing surfaces of the first and second flat plates at intervals such that their oscillation frequencies interfere with each other; and (d) first and second dielectric resonators. A dielectric substrate arranged in parallel with a plane parallel to the flat plate and (e) a first dielectric resonator formed by turning the first and second flat plates integrally about a predetermined position are drawn. A microstrip line disposed on the dielectric substrate at a distance along the trajectory for magnetic field coupling with the first dielectric resonator;
(F) The dielectric resonator control oscillator includes an oscillation circuit that oscillates at a frequency corresponding to the magnetic field coupling length between the microstrip line and the first dielectric resonator.

That is, according to the first aspect of the present invention, the first and second flat plates arranged parallel to each other at a predetermined interval by the holding means are moved parallel to each other about the predetermined position. It is held rotatably along the surface. And, on the opposing surfaces of the first and second flat plates,
The first and second dielectric resonators are mounted at intervals such that their oscillation frequencies interfere with each other. Also, the first
A dielectric substrate is arranged in parallel with the parallel surface of the second flat plate, and the first and second flat plates are integrally rotated about the predetermined position on the dielectric substrate. 1
The microstrip lines are arranged so as to leave an interval for magnetic field coupling with the first dielectric resonator along the locus drawn by the dielectric resonator of (1). Then, the oscillation circuit emits light at a frequency corresponding to the magnetic field coupling length between the microstrip line and the first dielectric resonator.

According to a second aspect of the present invention, in the dielectric resonator controlled oscillator according to the first aspect, the second dielectric resonator is a second dielectric resonator.
And fixed to the tip of a mounting member that is vertically mounted on the flat plate and is movable in a direction perpendicular to the parallel planes of the first and second flat plates.

That is, according to the second aspect of the present invention, the second end of the mounting member, which is vertically attached to the second flat plate and is movable in a direction perpendicular to the parallel surfaces of the first and second flat plates, is attached to the second flat plate.
Is fixed.

According to a third aspect of the present invention, in the dielectric resonator controlled oscillator according to the first aspect, the first dielectric resonator is a first dielectric resonator.
And fixed to the tip of a mounting member that is vertically mounted on the flat plate and is movable in a direction perpendicular to the parallel planes of the first and second flat plates.

That is, according to the third aspect of the present invention, the first end of the mounting member which is vertically mounted on the first flat plate and is movable in a direction perpendicular to the parallel planes of the first and second flat plates is attached to the first end.
Is fixed.

According to a fourth aspect of the present invention, in the dielectric resonator controlled oscillator of the first aspect, the holding means is capable of moving the first flat plate in a direction perpendicular to the parallel planes of the first and second flat plates. It is characterized by being held in.

That is, in the invention according to claim 4, the first flat plate is made movable by the holding means in a direction perpendicular to the parallel plane of the first and second flat plates and held.

According to a fifth aspect of the present invention, in the dielectric resonator controlled oscillator of the first aspect, the holding means is capable of moving the second flat plate in a direction perpendicular to the parallel planes of the first and second flat plates. It is characterized by being held in.

That is, in the invention according to claim 5, the second flat plate is movably held by the holding means in a direction perpendicular to the parallel plane of the first and second flat plates.

According to a sixth aspect of the present invention, there is provided the dielectric resonator controlled oscillator according to the first to fifth aspects, wherein the first and second dielectric resonator controlled oscillators are provided.
Are characterized by being fan-shaped flat plates.

That is, in the invention according to claim 6, the first and second flat plates are fan-shaped plates. Accordingly, when the first and second dielectric resonators are integrally rotated about a predetermined position, the space required for the rotation can be reduced, so that the configuration of the dielectric resonator controlled oscillator is reduced. The size can be reduced.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION

[0032]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to embodiments.

FIG. 1 shows an outline of the configuration of a dielectric resonator controlled oscillator according to an embodiment of the present invention. This dielectric resonator controlled oscillator has an opening at the top (not shown)
And a lid member 51 that covers an opening of the container 50. The plane constituting the bottom surface of the container 50 and the lid member 51 facing the opening of the container 50 are parallel to each other. A projecting portion 52 is formed on one side surface of the container 50, and the lid member 51 has a projecting portion 53 having the same cross-sectional shape on the same side surface. As described above, the protrusions 52 and 53 having the same cross-sectional shape parallel to the plane forming the bottom surface of the container 50 are provided with the container from the top surface of the lid member 51 in a direction perpendicular to the plane forming the bottom surface of the container 50. 5
A rotation shaft insertion portion 54 having a circular cross section is formed to a predetermined depth of zero. The flat plate constituting the bottom surface of the container 50 and the above-described protrusion 52 are provided with the protrusion 52
A notch portion 55 having a predetermined constant width is formed in parallel with the bottom surface of the container 50 from one end face where the groove 55 is formed. A flat plate parallel to a plane forming the bottom surface of the container 50 forming the lid member 51 is also placed on one end surface having the protruding portion 53 from the container 5.
A notch 56 having a predetermined constant width is formed in parallel with the bottom surface of the zero. Fan-shaped flat plates 57 and 58 each having a hole formed in a main portion thereof are inserted into these cutouts 55 and 56 with the fan-shaped flat surfaces parallel to the bottom surface of the container 50. Have been.

A rotary shaft 59 having a central axis perpendicular to a plane constituting the bottom surface of the container 50 and having a circular cross section is inserted into the rotary shaft insertion portion 56. further,
Holes are formed in essential parts of the fan-shaped plates 57, 58 inserted into the cutouts 55, 56 having predetermined widths, which are parallel to the planes constituting the bottom surface of the container 50,
The rotating shaft 59 is inserted into this hole. Fan plates 57, 58
Rotates around the rotation shaft 59 while maintaining a plane parallel to a plane constituting the bottom surface of the container 50 parallel to each other.

A main dielectric resonator (not shown) is arranged on a surface of the fan-shaped plate 57 inserted into the notch 55 and parallel to the bottom surface of the container 50. A columnar post 60 penetrating in a direction perpendicular to the surface of the fan-shaped plate 58 inserted into the cutout portion 56 is provided on a surface parallel to the bottom surface of the container 50, and a sub-post disposed at the end thereof is provided. A dielectric resonator (not shown) is arranged at a predetermined distance from the main dielectric resonator described above in the container 50. With such a configuration, the main dielectric resonator is attached to the fan-shaped plates 57 and 58 around the rotation axis 59 while maintaining a constant coupling distance between the main dielectric resonator and the sub-dielectric resonator. And the sub-dielectric resonator draws a locus of a predetermined arc.

Further, the post 60 is attached to the fan-shaped plate 58 so as to be movable in a direction perpendicular to a plane constituting the bottom surface of the container 50. In addition, the lid member 51 includes
A post 61 inserted through the fan-shaped plate 58 in a direction perpendicular to a plane parallel to the bottom surface of the container 50 has a slit 61 through which the post 60 protrudes and moves in an arc shape drawn around the rotation shaft 59. Are formed.

Hereinafter, the configuration of such a dielectric resonator controlled oscillator will be described in detail.

FIG. 2 is a top view of the dielectric resonator controlled oscillator shown in FIG. However, the same parts as those of the dielectric resonator control oscillator shown in FIG.
A description will be appropriately omitted. As described above, the slit 61 is formed in the lid member 51 in an arc shape drawn around the rotation shaft 59 inserted in the rotation shaft insertion portion 54 in which the post 60 is formed in the protrusion 53. The cross section of the protruding portion 53 is square or semicircular, and in the top view shown in FIG. 2, the cross section has a semicircular shape. The fan-shaped plate 58 is a fan-shaped flat plate, and a hole is formed at a main portion thereof. Such a fan-shaped plate 58 is rotatable around a rotation shaft 59 inserted into the hole. Further, a post 60 is inserted through the fan-shaped plate 58 in a direction perpendicular to the flat plate of the lid member 51. A disk-shaped sub-dielectric resonator 62 is attached to a surface of the fan-shaped plate 58 opposite to the slit 61 provided on the lid member 51. Thereby, the fan-shaped plate 58
Is rotated about the rotation shaft 59, the post 60 passing therethrough moves along the slit 61.

FIG. 3 shows a cross-sectional configuration of the dielectric resonator controlled oscillator shown in FIG. 2 when cut in the AA direction. However, the same portions as those of the dielectric resonator control oscillator shown in FIGS. 1 and 2 are denoted by the same reference numerals, and description thereof will be omitted as appropriate. A fan-shaped plate 57 inserted into a notch 55 formed parallel to the bottom surface from one end surface of the flat plate constituting the bottom surface of the container 50, and a bottom surface of the container 50 is constituted from one end surface of the flat plate constituting the lid member 51. A fan-shaped plate 58 inserted into a cutout portion 56 formed parallel to the plane is configured to be rotatable about a rotation shaft 59 while keeping the opposing surfaces parallel to each other. The fan-shaped plate 57 is provided with a columnar mounting member 63 perpendicular to the surface facing the fan-shaped plate 58, and a disk-shaped main dielectric resonator 64 at the tip thereof.
Is attached. A slit 66 having the same shape as the slit 61 is formed on the bottom surface of the container 50 so that the attachment member 63 attached to the fan-shaped plate 57 projects into the hollow portion 65 of the container 50. The main dielectric resonator 64 and the sub-dielectric resonator 62 are resonated by making the disc-shaped surfaces parallel to each other in the hollow portion 65 of the container 50 so that the oscillation frequencies interfere with each other. The frequency can be changed.

Further, on the bottom surface constituting the inner surface of the container 50, a printed board 67 as a dielectric board is arranged. An oscillation circuit including an active element, a ground plane, and a microstrip line is formed on the printed board 67. In particular, the microstrip line is formed along the shape of the slit 66 described above. That is,
The fan-shaped plates 57 and 58 rotate around the rotation shaft 59, and the microstrips are formed along the curvature of the arc drawn by the main dielectric oscillator 64 at the tip of the mounting member 63 disposed perpendicular to the rotation. Lines are formed on the printed circuit board 67. Thereby, the main dielectric resonator 64 attached to the attachment member 63 and the microstrip line on the printed circuit board 67 maintain the same coupling distance, and the coupling length d contributes to the magnetic coupling of the microstrip line shown in FIG. Can be adjusted.

Further, the slit 61 of the fan-shaped plate 58 described above
The sub-dielectric resonator 62 attached to the tip of the post 60 penetrating the main dielectric resonator 64 and the sub-dielectric resonator by integrally rotating the fan-shaped plates 57 and 58 via the rotation shaft 59. The coupling distance of the vessel 62 can be kept constant. With such a configuration, it is possible to adjust the coupling length d that contributes to the magnetic field coupling of the microstrip line while maintaining the resonance frequency determined by the coupling distance between the main dielectric resonator 64 and the sub-dielectric resonator 62. Can be.

The post 60 penetrating through the slit 61 formed in the fan-shaped plate 58 is movable in the arrow direction 68. As a result, the sub-dielectric resonator 62 attached to the tip of the post 60 is
4 can be changed, so that the resonance frequency can be easily adjusted.

FIG. 4 shows a cross-sectional configuration of the dielectric resonator controlled oscillator shown in FIG. 3 when cut in the BB direction. However, the same portions as those of the dielectric resonator controlled oscillator shown in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted as appropriate.
As described above, the printed board 67 is formed on the bottom surface constituting the inner surface of the container 50. This printed circuit board 6
A microstrip line 69 is formed on 7 along a slit 66 formed on the bottom surface of the container 50 in an arc shape of a predetermined length centered on the rotation axis 59. At both ends of the microstrip line 69, an active element 70 composed of a field effect transistor and a termination circuit 71 are electrically connected. The oscillating circuit configured as described above has a dielectric resonator, a microstrip line 69, and a dielectric oscillator having a resonance frequency determined by the coupling distance between the main dielectric oscillator 64 and the sub-dielectric oscillator 62. And oscillates at a predetermined frequency while satisfying the oscillation condition determined by the coupling length d for magnetic field coupling.

As described above, the dielectric resonator control oscillator according to the present embodiment has a dual-structure dielectric resonator composed of the main dielectric resonator 64 and the sub-dielectric resonator 62, each of which is provided on the rotation shaft 59. The attached opposing surfaces are provided so as to oppose two parallel fan-shaped plates 57 and 58. Then, the fan-shaped plates 57, 58 are structured so as to be rotatable integrally about the rotation shaft 59. Further, the microstrip line 69 is arranged on the dielectric substrate along the arc drawn by the main dielectric resonator 64.

Thus, while maintaining the resonance frequency determined by the main dielectric resonator and the sub-dielectric resonator having a predetermined coupling distance, the coupling distance between the microstrip line and the main dielectric resonator is further kept constant. In this state, it is possible to easily adjust only the coupling length d of the main dielectric resonator and the sub-dielectric resonator that contributes to the magnetic field coupling of the microstrip line. Therefore, the resonance frequency determined by the coupling distance between the main dielectric resonator and the sub-dielectric resonator satisfies the amplitude condition expressed by equation (3) as one of the oscillation conditions as in the related art, and is sufficiently wide. However, by fixing the main dielectric resonator, it is possible to solve the problem that the phase condition expressed by the expression (4) cannot be satisfied and the oscillating frequency cannot be widened.

Further, a post 60 penetrating through the fan-shaped plate 58
Is movable in the arrow direction 68, so that the sub-dielectric resonator 62 attached to the tip of the post 60 is
And the distance between the coupling and the main dielectric resonator 64 attached to the attachment member 63 of the fan-shaped plate 57 can be changed, so that the resonance frequency determined by the distance between these couplings can be easily changed. become. Therefore, since the oscillation frequency can be changed according to the microwave band oscillator to be applied, a dielectric resonator controlled oscillator having a wide application range can be provided.

Modification

In the dielectric resonator controlled oscillator according to the present embodiment, the main dielectric resonator and the sub dielectric resonator that move in an arc around the rotation axis 59 are provided with fan plates 57 and 58, respectively.
It was attached to. By making the sub-dielectric resonator 62 attached to the tip of the post 60 through the fan-shaped plate 58 movable in the arrow direction 68, the main dielectric resonator 64
In this case, the distance between the coupling and the auxiliary dielectric resonator 62 is changed. However, in the present modified example, the notch 56 is increased in the notch width, the mounting member similar to the mounting member 63 is mounted on the fan-shaped plate 58, and the sub-dielectric resonator 62 is fixed to the tip thereof. I do. Further, by making the fan-shaped plate 58 movable in the arrow direction 68 which is the axial direction of the rotation shaft 59, a sub-dielectric resonator 62 fixed to the tip of a mounting member vertically mounted on the fan-shaped plate 58; The inter-coupling distance with the main dielectric resonator 64 attached to the tip of the attachment member 63 attached vertically to the fan-shaped plate 57 is changed. This also makes it possible to easily change the resonance frequency determined by the distance between these couplings. Further, the attachment member attached to the fan-shaped plate 58 is
1 does not protrude outside, so that the size of the dielectric resonator controlled oscillator can be further reduced.

In the present embodiment and the modified example, the fan-shaped plate 57 and the fan-shaped plate 57 are
58 is arranged at a predetermined interval so as to be rotatable about the rotation shaft 59, but the present invention is not limited to this. It is sufficient that the fan-shaped plates 57, 58 can be held at a predetermined interval so that the fan-shaped plates 57, 58 are rotatable while keeping their opposing surfaces parallel.

In the dielectric resonator control oscillator according to the present embodiment and the modification, the post provided in the fan-shaped plate and inserted into the hole is made movable in the direction perpendicular to the parallel plane between the fan-shaped plates. Although the coupling distance between the main dielectric resonator and the sub-dielectric resonator is changed, the present invention is not limited to this. In short, it is only necessary that the coupling distance between the main dielectric resonator and the sub-dielectric resonator can be changed, and that the rotation can be performed around the rotation axis while maintaining the changed coupling distance.

In the dielectric resonator controlled oscillator according to the present embodiment and the modified example, the main dielectric resonator 64 is fixed and the sub-dielectric resonator 62 is movable in the arrow direction 68. However, the present invention is not limited to this. For example, the sub dielectric resonator 62 is fixed and the main dielectric resonator 6 is fixed.
The same effect can be obtained by making the 4 freely movable in the arrow direction 68.

In the dielectric resonator controlled oscillator according to the present embodiment and the modified example, the main dielectric resonator and the sub dielectric resonator that move in an arc around the rotation axis 59 are respectively mounted on the fan-shaped plates. However, the present invention is not limited to the shape of the flat plate on which the main dielectric resonator and the sub-dielectric resonator are mounted. However, if the fan-shaped plate is used, the configuration of the dielectric resonator control oscillator can be reduced in size.

[0053]

As described above, according to the first aspect of the present invention, while maintaining the resonance frequency determined by the first and second dielectric resonators having a predetermined coupling distance,
Further, it is possible to easily adjust only the coupling length d that contributes to the magnetic field coupling between the first dielectric resonator and the microstrip line while keeping the coupling distance between the microstrip line and the first dielectric resonator constant. become able to. As a result, the resonance frequency determined by the coupling distance between the first and second dielectric resonators satisfies the amplitude condition represented by Expression (3) as one of the oscillation conditions as in the related art, and has a sufficiently wide band. However, since the first or second dielectric resonator is fixed, the phase condition expressed by the equation (4) cannot be satisfied, and the oscillating frequency cannot be widened. Can be eliminated.

According to the second or third aspect of the invention, the distance between the first and second dielectric resonators can be changed, so that the resonance determined by the distance between these couplings can be changed. The frequency can be easily changed. Therefore, since the oscillation frequency can be changed according to the microwave band oscillator to be applied, a dielectric resonator controlled oscillator having a wide application range can be provided.

Further, according to the fourth or fifth aspect of the present invention, the distance between the first and second dielectric resonators can be changed by making the first and second flat plates movable. As a result, the resonance frequency determined by the distance between these couplings can be easily changed, and the size of the device configuration can be reduced more than when only the first and second dielectric resonators are movable. You can plan.

Further, according to the sixth aspect of the present invention, the first
Also, since the second flat plate is a fan-shaped plate, the space required for rotation can be reduced when the first and second dielectric resonators are integrally rotated about a predetermined position. The structure of the dielectric resonator controlled oscillator can be reduced in size.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an outline of a configuration of a dielectric resonator controlled oscillator according to an embodiment of the present invention.

FIG. 2 is a plan view of the dielectric resonator control oscillator according to the present embodiment as viewed from above.

FIG. 3 is a sectional view taken along line AA of the plan view shown in FIG. 2;

FIG. 4 is a sectional view taken along line BB of the sectional view shown in FIG. 3;

FIG. 5 is a perspective view showing an outline of a configuration of a conventionally proposed dielectric resonator control oscillator.

FIG. 6 is an equivalent circuit diagram showing an outline of an equivalent circuit configuration of a microwave band oscillator using a conventional TE01δ mode dielectric resonator.

7 is an equivalent circuit diagram showing an outline of a configuration of an equivalent circuit of each of a magnetic field coupling portion and a dielectric resonator of the equivalent circuit shown in FIG. 6;

8 is an equivalent circuit diagram equivalently showing a transformer and a parallel resonance circuit by another parallel resonance circuit in the equivalent circuit shown in FIG. 7;

[Explanation of symbols]

 REFERENCE SIGNS LIST 50 container 51 lid member 52, 53 projecting part 54 rotating shaft insertion part 55, 56 notch part 57, 58 fan-shaped plate 59 rotating shaft 60 post 61, 66 slit 62 auxiliary dielectric resonator 63 mounting member 64 main dielectric resonator 65 hollow part 67 printed circuit board 69 microstrip line 70 active element 71 termination circuit

Claims (6)

[Claims] 1. A first and a second flat plate which are arranged at a predetermined interval in parallel with each other, and the first and the second flat plate are placed on a parallel surface of the flat plate with the predetermined position as a center. Holding means rotatably holding the first and second flat plates, and first and second dielectric resonators attached to opposing surfaces of the first and second flat plates at intervals so that their oscillation frequencies interfere with each other. A dielectric substrate arranged in parallel with a plane parallel to the first and second flat plates, and a first substrate formed by integrally rotating the first and second flat plates around the predetermined position. A microstrip line disposed on the dielectric substrate at a distance that magnetically couples with the first dielectric resonator along a locus drawn by the dielectric resonator of the microstrip line; Magnetic field coupling length with dielectric resonator Dielectric resonator controlled oscillator, characterized by comprising an oscillation circuit which oscillates at the corresponding frequencies. 2. The tip of a mounting member, wherein the second dielectric resonator is vertically mounted on the second flat plate and is movable in a direction perpendicular to a parallel plane of the first and second flat plates. 2. A dielectric resonator controlled oscillator according to claim 1, wherein said oscillator is fixed to said oscillator. 3. The distal end of a mounting member, wherein the first dielectric resonator is suspended from the first flat plate and is movable in a direction perpendicular to a parallel plane of the first and second flat plates. 2. A dielectric resonator controlled oscillator according to claim 1, wherein said oscillator is fixed to said oscillator. 4. The dielectric according to claim 1, wherein said holding means holds said first flat plate so as to be movable in a direction perpendicular to a parallel plane of said first and second flat plates. Body resonator controlled oscillator. 5. The dielectric according to claim 1, wherein said holding means holds said second flat plate so as to be movable in a direction perpendicular to a parallel plane of said first and second flat plates. Body resonator controlled oscillator. 6. The dielectric resonator controlled oscillator according to claim 1, wherein said first and second flat plates are fan-shaped flat plates, respectively.