JP4650561B2 - Phase shifter - Google Patents

Description

  The present invention relates to a phase shifter capable of continuously changing the phase of a signal.

The array antenna has a plurality of antenna elements, and the beam tilt angle (directivity) of the array antenna can be changed by adjusting the phase difference between the antenna elements. And in order to adjust the phase difference between antenna elements, the technique which uses a distribution phase shifter is proposed conventionally (for example, refer patent document 1).
This conventional distribution phase shifter has an arc-shaped fixed conductor on the output side, a center conductor on the input side provided at the center position of the arc-shaped fixed conductor, and the fixed conductor and the center conductor in an insulating film. And a rotationally coupled conductor that is electrostatically coupled via the.

In order to stabilize the characteristics of the distribution phase shifter configured as described above, for example, the distribution characteristics and the VSWR characteristics, it is necessary to couple the rotary coupling conductor and the fixed conductor in a stable state. That is, since the rotation coupling conductor and the fixed conductor are coupled (electrostatic coupling) via an insulating film, when the rotation coupling conductor is rotated, the rotation coupling conductor and the fixed conductor are not connected. This is because the capacitance changes and the characteristics of the distribution phase shifter change when the dimensions of the change.
Therefore, in such a distributed phase shifter, it is necessary to couple the rotationally coupled conductor and the fixed conductor in a stable state, and it is possible to ensure repeated reproducibility at the time of phase shift and to eliminate individual differences in the distributed phase shifter. There is a need for a configuration that can be used.

JP 2001-284902 A (see FIG. 2)

As described in FIG. 8 of Patent Document 1, in this distributed phase shifter, the rotationally coupled conductor and the stationary conductor are brought into pressure contact with the rotationally coupled conductor by a spring on the substrate side on which the stationary conductor is provided. The dimension between is made constant.
However, it is considered that a structure that does not apply a load is preferable to a structure that applies a load to the rotary coupling conductor using such a spring mechanism. In addition, it is preferable to simplify the configuration for coupling the rotary coupling conductor and the fixed conductor in a stable state.

  Therefore, an object of the present invention is to provide a phase shifter that can be provided with stable characteristics by new technical means.

  (1) The phase shifter according to the present invention includes an output-side conductor whose end is an output end, an input-side conductor to which a high-frequency signal is input, and the high-frequency signal input to the input-side conductor to the output-side conductor. A movable coupling conductor for transmitting to the output end of the first and second movable coupling conductors, and the movable coupling conductor is movable along the output-side conductor and the input-side base coupled to the input-side conductor via an insulator. And an output-side movable part that is coupled to the output-side conductor via an insulator, and a line part that electrically connects the input-side base part and the output-side movable part. The side movable portion includes a first output portion and a second output portion that are connected in parallel to the line portion and provided in a state where the output side conductor is disposed therebetween.

According to the present invention, the output side conductor is disposed between the first output part and the second output part of the output side movable part of the movable coupling conductor, and the output side movable part and the output side conductor are connected to each other. Since it is connected via an insulator, the output side movable part and the output side conducting wire relatively change their positions in the opposing direction of the first output part and the second output part, so that the first output part and Even if the electrostatic capacity between any one of the second output sections and the output-side conductor increases, the capacitance between the other output section and the output-side conductor decreases. Therefore, since the change as a whole becomes small (that is, it is difficult to be affected by the position change), the characteristics of the phase shifter can be stabilized.
The insulator includes air in addition to an insulating member made of resin or the like. When the insulator is a resin, for example, polyethylene terephthalate, polyethylene, polyacetal, or the like can be used in addition to a fluororesin such as polytetrafluoroethylene. In this case, a thin sheet is preferable.

(2) Moreover, the said input side conductor shall be the structure which has the 1st input conductor part and the 2nd input conductor part which were provided in the state connected in parallel and arrange | positioning the said input side base part in between. Can do.
In this case, since the input side base is disposed between the first input conductor portion and the second input conductor portion of the input side conductor, and the input side conductor and the input side base are coupled via an insulator, In the opposing direction of the first input conductor portion and the second input conductor portion, the position of the input side conductor and the input side base portion changes relatively, so that the first input conductor portion and the second input conductor portion Even if the capacitance between one of the input conductor portions and the input side base portion increases, the capacitance between the other input conductor portion and the input side base portion decreases, so that the overall change occurs. Therefore, the characteristics of the phase shifter can be stabilized.

(3) Or, the input side base has a first input base and a second input base that are connected in parallel to the line portion and provided with the input conductor disposed therebetween It can be.
In this case, the input-side conductor is disposed between the first input base and the second input base of the input-side base that the movable coupling conductor has, and the input-side conductor and the input-side base are interposed via an insulator. Since the first input base and the second input base are relatively displaced in the opposing direction of the first input base and the second input base, the first input base and the second input base Even if the capacitance between any one of the input bases and the input-side conductor increases, the capacitance between the other input base and the input-side conductors decreases, resulting in a change as a whole. Therefore, the characteristics of the phase shifter can be stabilized.

(4) The output-side movable part is connected in parallel to the line part, and the output-side conductor is disposed in a direction perpendicular to the opposing direction of the first output part and the second output part. It is preferable to have the 3rd output part and the 4th output part which were provided facing as a state.
In this case, with respect to the opposing direction of the third output part and the fourth output part orthogonal to the opposing direction of the first output part and the second output part, the position of the output side lead wire and the output side movable part is relatively changed. Even so, the characteristics of the phase shifter can be stabilized.

(5) An input terminal portion having a first terminal connected to the input-side conductor, a second terminal provided insulated from the first terminal, and the second terminal electrically And a pair of plate-like outer conductors connected to each other and facing each other, and the phase shifter body comprising the output-side conductor, the input-side conductor, and the movable coupling conductor, It is preferable to be arranged at a substantially intermediate position.
In this case, even if the gap dimension between one outer conductor and the phase shifter body increases, the gap dimension between the other outer conductor and the phase shifter body decreases, so that the impedance of the entire phase shifter Can be suppressed.

(6) The output-side conductor is an arc or a ring-shaped line with a part opened, and the input-side conductor is a conductor provided on a center line of the arc or a part-open ring. And the input side base of the movable coupling conductor is a rotationally symmetric conductor with respect to the center line, and is connected to the input side conductor and receives a high-frequency signal and is provided on the center line. It is preferable that the input side base portion of the movable coupling conductor is attached to the conductor shaft via an insulator so as to be rotatable around the center line of the conductor shaft.
In this case, the high-frequency signal input from the conductor axis to the input side conductor propagates through the movable coupling conductor and is transmitted to the output side conductor to the flow end. When the movable coupling conductor is rotated around the center line, the phase of the signal transmitted to the end portion can be changed.
Further, the input side base of the movable coupling conductor is rotationally symmetrical (for example, circular) with respect to the center line, and the input side base rotates around the center line, so that the relative position with the input side conductor remains unchanged. As a result, it is possible to suppress a change in high-frequency characteristics at the joint between the input-side conductor and the input-side base. The center line referred to here is a line extending in a direction perpendicular to the plane including the circular arc or part of the output-side conducting wire, and the center point of the circular arc or part of the circular ring is open. It is a line that passes through.

  (7) Further, according to the present invention, an output-side conductor whose end is an output terminal, an input-side conductor to which a high-frequency signal is input, and the high-frequency signal input from the input-side conductor are output from the output-side conductor. A movable coupling conductor for transmitting to the end, the movable coupling conductor being movable along an input side base coupled to the input side conductor via an insulator and the output side conductor. An output-side movable portion coupled to the output-side conductor via an insulator; and a line portion electrically connecting the input-side base and the output-side movable portion, the output-side conductor Has a first output conductor part and a second output conductor part that are connected in parallel and provided with the output side movable part disposed therebetween.

According to the present invention, the output-side movable part of the movable coupling conductor is disposed between the first output conductor part and the second output conductor part of the output-side conductor, and the output-side conductor and the output-side movable part are insulated. Since the output side conducting wire and the output side movable portion are relatively moved in the opposite direction of the first output conducting portion and the second output conducting portion, the first output conducting portion is connected. And the second output conductor portion, even if the electrostatic capacitance between the output conductor portion and the output side movable portion increases, the static electricity between the other output conductor portion and the output side movable portion is increased. Since the overall change is reduced by reducing the capacitance, the characteristics of the phase shifter can be stabilized.
The insulator includes air in addition to an insulating member made of resin or the like.

  (8) Further, according to the present invention, an output side conducting wire whose end is an output end, an input side conductor to which a high frequency signal is input, and the high frequency signal inputted to the input side conductor are output from the output side conducting wire. A movable coupling conductor for transmitting to the end, the movable coupling conductor being movable along an input side base coupled to the input side conductor via an insulator and the output side conductor. An output-side movable part coupled to the output-side conductor via an insulator, and a line part electrically connecting the input-side base part and the output-side movable part, and the output-side movable part The part has a cylindrical shape surrounding a part in the longitudinal direction of the output-side conductor in the circumferential direction via the insulator.

  According to the present invention, the output side movable portion of the movable coupling conductor has a cylindrical shape that surrounds a part of the longitudinal direction of the output side conductor in the circumferential direction via the insulator. Since the movable portion and the output side conducting wire are relatively displaced in an arbitrary direction, the interval between the wall portion on one side in the displacement direction in the peripheral wall of the output side movable portion and the output side conducting wire is narrowed. Even if the capacitance increases, the distance between the wall on the other side in the displacement direction and the output-side conductor becomes wider and the capacitance decreases, so the overall change becomes smaller. The characteristics can be stabilized.

  According to the present invention, the characteristics of the phase shifter can be stabilized even if the position of the output side conductor and the output side movable portion is relatively changed. The tilt angle can be accurately changed.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First embodiment]
FIG. 1 is a perspective view showing a part of the phase shifter of the present invention. The phase shifter of the following embodiment is a distribution phase shifter A that can perform power distribution of a high-frequency signal and can continuously change the phase difference of the distributed signal.
This distribution phase shifter A includes an output side conductor 1 having both ends serving as output ends 1a and 1b, an input side conductor 2 provided away from the output side conductor 1 and receiving a high frequency signal, and an input side conductor 2 And a movable coupling conductor 3 for distributing and transmitting the high-frequency signal input to the output terminals 1a and 1b of the output-side conductor 1 to each other.

The output-side conductor 1 is a strip line having an arc shape with a radius r centered on the center line C (or may be an annular shape with a part opened).
The input-side conductor 2 is a conductor provided on the center line C, and has a circular shape centered on the center line C. 1 includes two first input conductor portions 31 (referred to as first input elements 31) and second input conductor portions 32 (referred to as second input elements 32) arranged in the direction of the center line C. And have. The first input conductor portion 31 and the second input conductor portion 32 are connected in parallel to a conductor shaft 6 described later.

The movable coupling conductor 3 includes an input side base portion 11 coupled to the input side conductor 2 via insulators 4 and 4, and an output side movable portion 13 coupled to the output side conductor 1 via the insulator 5. The input side base portion 11 and the output side movable portion 13 are connected to each other and have a linear line portion 12 that is electrically connected to each other.
The line portion 12 is a conductor extending in the radius r direction from the center line C, the input side base portion 11 is connected to one end portion, and the output side movable portion 13 is connected to the other end portion.

In FIG. 1, the output side movable portion 13 is formed in an arc shape having the same radius r as that of the output side conducting wire 1. The output side movable portion 13 includes a first portion 13a extending from the line portion 12 to the one output end 1a side along the longitudinal direction of the output side conducting wire 1, and from the line portion 12 to the other output end 1b side. And a second portion 13b extending. Equivalently, the line portion 12 and the output side conductor 1 are connected between the first and second portions 13a and 13b (the center portion of the output side movable portion 13).
FIG. 2A is a cross-sectional view of the output side coupling portion Q having the output side movable portion 13 and the output side conducting wire 1 of the movable coupling conductor 3. As will be described later, the output-side movable unit 13 is a first output unit 21 (first output element) provided on both (upper and lower) sides of the output-side conductor 1 with a part of the output-side conductor 1 disposed therebetween. 21) and a second output portion 22 (referred to as a second output element 22). The first output unit 21 and the second output unit 22 are connected to the line unit 12 in parallel.
In the form of FIG. 2A, the first output element 21 and the second output element 22 are branched from the line portion 12 so as to be (vertical) symmetrical. The center of the movable coupling conductor 3 in the thickness direction and the center of the output side conductor 1 in the thickness direction are on the same plane.
2B is a modification of the output side coupling portion Q, and the first output element 21 and the second output element 22 are branched from the line portion 12 so as to be asymmetric. The first output unit 21 and the line unit 12 are on substantially the same plane.

FIG. 3 is a cross-sectional view of the input side coupling portion P having the input side base 11 and the input side conductor 2 of the movable coupling conductor 3. The input side base portion 11 is a rotationally symmetric conductor centered on the center line C, and has an annular shape having the same contour shape as the first input element 31 and the second input element 32.
Further, the metal conductor shaft 6 is provided with the center line C as an axis. The first input element 31 and the second input element 32 are connected to the end of the conductor shaft 6, and the first input element 31 and the second input element 32 are electrically connected to the end of the conductor shaft 6. Are connected in parallel.

The conductor shaft 6 is in a state of being connected to the input-side conductor 2 (the first input element 31 and the second input element 32), and a high-frequency signal is input from a cable not shown.
The input base 11 of the movable coupling conductor 3 is attached to the conductor shaft 6 via the insulator 4 so as to be rotatable around the center line C.
Therefore, the output side movable portion 13 is moved along the output side conducting wire 1 when the input side base portion 11 rotates around the center line C.

With the above configuration, the high-frequency signal input from the conductor shaft 6 to the input-side conductor 2 is transmitted to the input-side base 11 of the movable coupling conductor 3 through the insulator 4 and propagates through the line portion 12 of the movable coupling conductor 3. The high-frequency signal flows from the output-side movable part 13 (see FIG. 2) of the movable coupling conductor 3 to the output-side conductor 1 via the insulator 5 and is distributed to the output ends 1a and 1b at both ends of the output-side conductor 1. Is done.
Then, by rotating the movable coupling conductor 3 around the center line C, the line length from the input-side conductor 2 to the output ends 1a and 1b of the output-side conductor 1 changes, and the change in the line length causes the output end to change. The phase difference of the high frequency signal distributed to 1a and 1b can be changed.

Further, the characteristic impedance on the input side conductor 2 side is set to 50 Ω, for example, and the characteristic impedance of the output side conductor 1 is set to 100 Ω (twice the input side) (for example, the width of the conductor). Yes.
The impedance of the output-side conductor 1 viewed from the line portion 12 of the movable coupling conductor 3 is 50Ω because the two output-side conductors 1 having a characteristic impedance of 100Ω are connected in parallel. Therefore, the impedance is the same on the input / output side.

  Further, the configuration of the output side movable portion 13 of the movable coupling conductor 3 will be further described. In FIG. 2, the output-side movable part 13 is branched from the linear line part 13 so as to face each other (with the output-side conductor 1 in between) and the second output element 21. And an output element 22. And the output side conducting wire 1 is interposed between the first output element 21 and the second output element 22, the insulator 5a is interposed between the first output element 21 and the output side conducting wire 1, and the second An insulator 5b is interposed between the output element 22 and the output-side conductor 1.

  In the embodiment of FIG. 2, the insulator 5a and the insulator 5b are integral. The insulators (insulating members) 5a and 5b are made of, for example, a fluororesin. The insulators 5 a and 5 b are attached to the inner surface of the output side movable portion 13. Thereby, the output side movable part 13 which has the insulators 5a and 5b slides along the output side conducting wire 1. FIG. Although not shown, the insulators 5 a and 5 b may be attached to both surfaces of the output side conductor 1.

As described above, the first output element 21 and the second output element 22 of the output side movable portion 13 included in the movable coupling conductor 3 are connected in parallel to the line portion 12, and the first output element 21 and the second output element are connected. Since the output side conducting wire 1 is disposed between the output side conducting wire 1 and the output side movable portion 13, the opposing direction of the first output element 21 and the second output element 22 (center line in FIG. 1). (In the direction C), for example, the distance A1 (see FIG. 2) between the first output element 21 and the output-side conductor 1 is reduced, and the capacitance between the two increases. Even so, the distance B1 (see FIG. 2) between the second output element 22 and the output-side conductor 1 is increased, and the capacitance between the two is reduced.
That is, as shown in the equivalent circuit diagram of the coupling portion Q between the output side movable portion 13 and the output side conductor 1 in FIG. 4, the coupling portion Q is equivalent to a model in which capacitors C1 and C2 are connected in parallel. Even if the capacitance increases by a certain value in one capacitor C1, if the capacitance decreases by a certain value in the other capacitor C2, the capacitance does not change as a whole circuit (change in capacitance). Is suppressed). Therefore, even if the output side movable part 13 and the output side conducting wire 1 are relatively displaced in the direction of the center line C in FIG. 1, the change in the characteristics of the distribution phase shifter A can be suppressed to a small extent due to the displacement.

  Further, the configuration of the input side conductor 2 will be further described. In FIG. 3, the input-side conductor 2 includes the first input element 31 and the second input element provided on both (upper and lower) sides of the input-side base 11 with the annular input-side base 11 disposed therebetween. 32. That is, the input-side conductor 2 includes the first input element 31 and the second input element 32 that are formed so as to face each other with the input-side base 11 interposed therebetween. An insulator 4 a is interposed between the first input element 31 and the input side base 11, and an insulator 4 b is interposed between the second input element 32 and the input side base 11.

  As described above, the first input element 31 and the second input element 32 of the input-side conductor 2 are connected in parallel to the conductor shaft 6, and the movable coupling conductor 3 is interposed between the first input element 31 and the second input element 32. Since the input-side base 11 is disposed, the input-side conductor 2 and the input-side base 11 are opposed to the first input element 31 and the second input element 32 (in the direction of the center line C in FIG. 1). By changing the position relatively, for example, even if the distance A2 (see FIG. 3) between the first input element 31 and the input side base 11 changes and the capacitance between them increases, the second input element The capacitance of the space B2 (see FIG. 3) between the input side base 11 and the input side base 11 is reduced, so that the overall change is small (similar to FIG. 4). Therefore, even if the input side base 11 and the input side conductor 2 of the movable coupling conductor 3 are relatively displaced in the direction of the center line C, the change in the characteristics of the distribution phase shifter A can be suppressed.

In order to change the rotation angle around the input-side conductor 2 by rotating the movable coupling conductor 3 around the center line C, a slight gap is provided at the coupling portions P and Q. It is preferable. For example, in FIG. 2, a gap is preferably provided between the insulator 5 fixed to the output side movable portion 13 and the output side conductor 1. This is because the output side movable portion 13 is a movable object, and therefore a gap is required to move it smoothly. Therefore, by providing such a gap, there is a possibility that the movable coupling conductor 3 and the input-side conductor 2 are displaced in the direction of the center line C. However, according to the present invention, it is possible to suppress a change in capacitance at the coupling portions P and Q, and thus it is possible to reduce the influence of the gap on the characteristics of the distribution phase shifter A.
Further, as described above, the input side base 11 of the movable coupling conductor 3 is circular (rotationally symmetric) about the center line C, and the input side base 11 rotates around the center line C. The relative position with respect to the input-side conductor 2 remains unchanged. As a result, the high frequency characteristics at the joint P between the input side conductor 2 and the input side base 11 do not change.

FIG. 5 is a cross-sectional view showing a modification of the output side movable portion 13. The output side movable portion 13 has a cylindrical shape surrounding the output side conducting wire 1 in the circumferential direction. That is, the output side movable portion 13 has an annular cross section, and in order to obtain this shape, the output side movable portion 13 includes the first output element 21 in addition to the first output element 21 and the second output element 22. 21 and the second output element 22 are provided so as to face each other in a direction (radius r direction) orthogonal to the facing direction (the direction of the center line C in FIG. 1) with the output-side conductor 1 disposed therebetween. It has the 3rd output part 23 (3rd output element 23) and the 4th output part 24 (4th output element 24). The third output element 23 and the fourth output element 24 are in a state of being connected in parallel to the line portion 12.
In this case, similarly to the configuration of FIG. 2, even if the output side movable portion 13 and the output side conducting wire 1 are relatively displaced in the direction of the center line C in FIG. In addition, even if the output side movable portion 13 and the output side conducting wire 1 relatively change their positions in the radius r direction, the characteristics of the coupling portion Q can be stabilized.

FIG. 6 is a cross-sectional view of the input-side coupling portion P having the input-side base 11 and the input-side conductor 2 of the movable coupling conductor 3. The coupling portion P in FIG. 6 is a modification of the coupling portion P in FIG. In the form of FIG. 6, the form of the conductor axis | shaft 6 into which a high frequency signal is input from the cable outside a figure differs. In order to connect the input side conductor 2 (the first input element 31 and the second input element 32) in parallel to the conductor shaft 6, the conductor shaft 6 includes a shaft body 6b and a screw provided at the tip thereof. And a shaft portion 6a. Then, by screwing the nut 15 into the screw shaft portion 6a, the first input element 31 and the second input element 32 are interposed between the nut 15 and the end surface of the shaft body 6b with the spacer 16 interposed therebetween. Is attached.
The input side base 11 of the movable coupling conductor 3 is attached to the conductor shaft 6 via the insulator 4 so as to be rotatable around the axis (center line C) of the screw shaft 6a. According to this configuration, the input-side coupling portion P can be easily configured.

FIG. 7 is a sectional view of the distribution phase shifter A. The distribution phase shifter A has a metal case 8 and an input terminal portion 7 to which a cable (not shown) is connected. The output side conductor 1 and the input side conductor 2 are provided in the case 8. And the phase shifter main body 9 provided with the movable coupling conductor 3 is accommodated. In FIG. 7, a signal is sent from one input-side conductor 2 to two output-side conductors 1 via two movable coupling conductors 3. That is, the arc-shaped output-side conductive wire 1 and the movable coupling conductor 3 shown in FIG.
The housing 8 includes a pair of planar plate-like upper conductors (outer conductors) 17 and lower conductors (outer conductors) 18 disposed in opposition to the center line C direction, and the upper conductors 17 and the lower conductors 18. The peripheral wall conductor 19 is connected.

The input terminal portion 7 has a first terminal connected to the input-side conductor 2 and a second terminal provided so as to be insulated from the first terminal. As shown in FIG. 3, the first terminal is made of the conductor shaft 6, the second terminal is made of metal and made of a cylindrical tube conductor 26, and an insulator is provided between the conductor shaft 6 and the tube conductor 26. 27 is interposed.
The conductor shaft (first terminal) 6 is electrically connected to the input-side conductor 2, and the pair of upper conductor 17 and lower conductor 18 are electrically connected to the cylindrical conductor (second terminal) 26. ing. A high frequency signal is fed to the input terminal portion 7 having the conductor shaft 6 and the cylindrical conductor 26.

As shown in FIG. 7, the phase shifter body 9 (the output side conductor 1, the input side conductor 2, and the movable coupling conductor 3) is disposed at an intermediate position between the upper conductor 17 and the lower conductor 18 of the pair. (M1 = M2 in FIG. 7).
According to this configuration, for example, even if the distance M1 between the upper conductor 17 and the phase shifter body 9 is increased, the other distance M2 between the lower conductor 18 and the phase shifter body 9 is decreased. The change in impedance in the entire phase shifter A can be reduced.

[Second Embodiment]
FIG. 8 is a perspective view showing a part of the distributed phase shifter of the present invention. The distribution phase shifter of the embodiment of FIG. 8 is provided separately from the output side conductor 51 having both ends serving as output ends 51a and 51b and the output side conductor 51, as in the embodiment of FIG. And a movable coupling conductor 53 for distributing and transmitting a high-frequency signal input to the input-side conductor 52 to both output ends 51a and 51b of the output-side conductor 51. The overall arrangement of the output-side conductor 51, the input-side conductor 52, and the movable coupling conductor 53, and the dimensions such as the radius r are the same as those in the embodiment of FIG.

  Further, similarly to the embodiment of FIG. 1, the movable coupling conductor 53 is movable along the input-side base 61 and the output-side conductor 51 that are coupled to the input-side conductor 52 via the insulator 54, and The output side movable portion 63 coupled to the output side conductive wire 51 via the insulator 55, and the line portion 62 that electrically connects the input side base portion 61 and the output side movable portion 63. Yes.

The difference between the distributed phase shifter of the embodiment of FIG. 8 and the distributed phase shifter of FIG. 1 is the form of the coupling portion P on the input side and the coupling portion Q on the output side.
First, the output side coupling unit Q in FIG. 8 will be described. FIG. 9 is a cross-sectional view of the output side coupling portion Q of FIG. The output side conducting wire 51 has the first output conducting wire portion 71 and the second output conducting wire portion 72 formed so as to face each other. The first output conductor portion 71 and the second output conductor portion 72 are arc-shaped lines having a radius r with the center line C as the center (or may be an annular shape with a part opened). The first output conducting wire portion 71 and the second output conducting wire portion 72 are configured to be connected in parallel to the output ends 51 a and 51 b of the output side conducting wire 51.
The first output conducting wire portion 71 and the first output conducting wire portion 72 are connected by a plate-like conductor 73 and connected in parallel, as shown by a two-dot chain line in FIG.
The conductor 73 may be provided over the entire length in the longitudinal direction of the output side conductor 51, and the output side conductor 51 may have a U-shaped cross section over the entire length. However, the conductor 73 is partially connected (for example, at both ends) by the conductor 73. It may be.
Or in order to make it the structure which connected the 1st output conducting wire part 71 and the 2nd output conducting wire part 72 in parallel with respect to the output ends 51a and 51b of the output side conducting wire 51, it shows to the output end 51a side of FIG. As described above, the end face in the longitudinal direction of the first output conductor portion 71 and the end face in the longitudinal direction of the second output conductor portion 72 may be connected by the conductor 74.

  An output side movable portion 63 of the movable coupling conductor 53 is interposed between the first output conductor portion 71 and the second output conductor portion 72. That is, the first output conductor 71 and the second output conductor 72 are provided on both sides (in the direction of the center line C) of the output movable portion 63 with the output movable portion 63 disposed therebetween. Yes. An insulator 55a is interposed between the first output conductor portion 71 and the output side movable portion 63, and an insulator 55b is interposed between the second output conductor portion 72 and the output side movable portion 63.

  As described above, the first output conductor 71 and the second output conductor 72 of the output-side conductor 51 are connected in parallel, and the movable coupling conductor is provided between the first output conductor 71 and the second output conductor 72. 53, the output side movable part 63 is disposed, and the output side conductive line 51 and the output side movable part 63 are coupled via the insulator 55. Therefore, the output side conductive line 51 and the output side movable part 63 are centered. Even if the electrostatic capacity between the first output conducting wire portion 71 and the output side movable portion 63 (gap A1 in FIG. 9) increases by changing the position relatively in the direction of the line C, for example, The capacitance between the second output conducting wire portion 72 and the output side movable portion 63 (gap B1 in FIG. 9) is reduced, so that the overall capacitance changes as in the embodiment of FIG. And the characteristics of the distributed phase shifter A can be stabilized.

Next, the coupling part P on the input side will be described with reference to FIGS. FIG. 11 is a cross-sectional view of the coupling portion P. The input-side conductor 52 is a conductor provided on the center line C, and is made of a conductor having a circular shape centered on the center line C. The input side base 61 of the movable coupling conductor 53 is a rotationally symmetric conductor having the center line C as the center, and has an annular shape having the same outline shape as the input side conductor 52.
The input-side base 61 has two first input bases (first input elements) 81 and second input bases (second input elements) 82 arranged in the center line C direction. The first input element 81 and the second input element 82 are provided on both sides of the input side conductor 52 with the input side conductor 52 disposed therebetween. The first input element 81 and the second input element 82 are connected in parallel to the line portion 62.

The metal conductor shaft 6 is provided with the center line C as an axis. The input side conductor 52 is electrically connected to the conductor shaft 6. In addition, the first input element 81 and the second input element 82 of the input side base 61 included in the movable coupling conductor 53 can be rotated around the center line C via the insulator 54 so that the conductor shaft 6 can be rotated. Is attached.
Therefore, the output side movable portion 53 moves along the output side conducting wire 51 by rotating the input side base portion 61 around the center line C.
The portion of the conductor shaft 6 on the tip side (upper side in FIG. 11) than the input-side conductor 52 may be made of resin, or the portion may not be provided. In this case, a high-frequency signal is input to the input-side conductor 52 using the conductor shaft 6 as a coaxial inner conductor.
Alternatively, the entire conductor shaft 6 may be made of resin. In this case, a high-frequency signal is input to the input-side conductor 52 through a conducting wire (not shown), and the first input element 81 and the second input element 82 can be rotated around the center line C (insulator 54). Can be directly attached to the conductor shaft 6.

  According to the input-side coupling portion P, the first input element 81 and the second input element 82 of the input-side base 61 included in the movable coupling conductor 53 are connected in parallel to the line portion 62, and the first Since the input-side conductor 51 is disposed between the input element 81 and the second input element 82 and the input-side conductor 52 and the input-side base 61 are coupled via the insulator 54, the input-side conductor 52 and The position of the input side base 61 is relatively changed in the opposing direction of the first input element 81 and the second input element 82, so that, for example, the static between the first input element 81 and the input side conductor 52 is achieved. Even if the capacitance increases, the capacitance between the second input element 82 and the input-side conductor 52 decreases, so that the overall change is reduced, so that the characteristics of the distributed phase shifter can be stabilized. it can.

1 may be applied to the input-side coupling portion P shown in FIG. 8, and the distributed phase shifter shown in FIG. 8 may be applied. The coupling portion P on the input side of A may be applied to the coupling portion P on the input side shown in FIG.
In each of the above embodiments, since the input side conductor 2 and the movable coupling conductor 3 and the movable coupling conductor 3 and the output side conductor 1 are coupled via an insulator, There is no metal contact, and the occurrence of intermodulation wave distortion can be prevented.

[Third embodiment]
FIG. 10 is a perspective view showing a part of the distribution phase shifter of the present invention. The form of FIG. 10 differs from the form of FIG. 1 in that the output side movable portion 13 of the movable coupling conductor 3 has a cylindrical shape surrounding a part of the longitudinal direction of the output side conductor 1 in the circumferential direction via the insulator 5. It is a point. That is, the cylindrical output side movable portion 13 has a shape surrounding the output side conducting wire 1 from the entire circumference. About another structure, it is the same as that of the form of FIG.
Note that the output side movable portion 13 may have an annular cross section, and in the form of FIG. 10, the input side conductor 1 is made of a strip conductor, and accordingly, the cross sectional shape is an ellipse (ellipse). The cross-sectional shape may be a rectangle or a rectangle whose corners are arcs.
Moreover, the coupling part P on the input side in this form may be the one described in another form.

  According to this form, when the output side movable part 13 and the output side conducting wire 1 are relatively displaced in an arbitrary direction (for example, the arrow V direction in FIG. 10), the displacement within the peripheral wall of the output side movable part 13. The capacitance between the wall portion 20a on the one side in the direction and the output-side conductor 1 is reduced and the capacitance is increased. As the capacitance decreases, the overall change becomes smaller, and the characteristics of the distributed phase shifter A can be stabilized.

[Fourth embodiment]
FIG. 12 is a perspective view showing a part of the distributed phase shifter of the present invention. The distribution phase shifter A of FIG. 12 is provided with a plurality (two) of output-side conductors 1 for one input-side conductor 2 and is movable in accordance with the number of output-side conductors 1. The coupling conductor 3 has the same number (two) of output side movable parts 13. The form of FIG. 12 differs from the form of FIG. 7 in that a plurality of output-side conductors 1 and a plurality of output-side movable parts 13 are provided on the same side in the radius r direction with the center line C as the center. is there. That is, the plurality of output-side conductors 1 (output-side movable portion 13) are arranged away from each other in the radial direction from the center line C. The shapes of all the output side conductors 1 and all the output side movable portions 13 are circular arcs around one center line C or an annular shape with a part thereof opened. Thus, by moving one movable coupling conductor 3, the phase of the signal can be continuously changed at each of the four output ends 1a, 1b, 1c, and 1d. Also in this case, a four distribution type distribution phase shifter A having four output terminals 1a, 1b, 1c, and 1d can be obtained by one distribution phase shifter A.

  In each of the above embodiments, the phase difference between the output ends 1a and 1b (51a and 51b) of the output-side conductor 1 can be adjusted by moving the movable coupling conductor 3 (53). If the configured distribution phase shifter A is used to change the beam tilt angle of the array antenna, even if the relative positions of the output-side conductor 1 (51) and the movable coupling conductor 3 (53) change, and Even if the input-side conductor 2 (52) and the movable coupling conductor 3 (53) change in position relatively, the change in capacitance at the coupling portions P and Q is small. It can be stabilized. For this reason, it is possible to accurately change the beam tilt angle of the array antenna using this distributed phase shifter A, and to ensure reproducibility at the time of phase shifting, or to detect the individual differences of a plurality of distributed phase shifters A. Can be eliminated.

In addition, with respect to the present invention, the embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is not meant to be described above, but is intended to include all modifications within the meaning and scope equivalent to the scope of the claims.
For example, in the above-described embodiment, the input-side base 11 (61) of the movable coupling conductor 3 (53) rotates around the center line C, so that the output-side movable section 13 (63) of the movable coupling conductor 3 (53). However, although the distribution phase shifter of the present invention is not shown in the drawing, the input side conductor is linear and the output side conductor is not shown. The movable coupling conductor may be moved along the input-side conductor and the output-side conductor.
Further, the output side conductor and the movable coupling conductor are preferably a strip line (triplate line) disposed in the center between the outer conductors, but may be a microstrip line.

In the embodiment (for example, FIG. 1), the configuration in which the output side movable portion 13 branches and has the two output elements 21 and 22 has been described. However, the number of branches (the number in parallel) is not limited to 2, but 3 or more. There may be. Even in this case, what is necessary is just to comprise so that the output element of the output side movable part 13 and the output element of the output side conducting wire 1 may mutually overlap via an insulator.
That is, in the embodiment (for example, FIG. 1 and FIG. 2), with respect to the output-side coupling portion Q, the output-side movable portion 13 of the movable coupling conductor 3 is divided into two first output elements 21 that are branched and connected in parallel. The second output element 22 (in this case, two branches), the single input side conductor 2 is sandwiched between them, but as another example, for example, as shown in FIG. The output side movable part 13 has three first output elements 14a, second output elements 14b, and third output elements 14c connected in parallel to the line part 12 (in this case, three branches), and the output side conductor 1 is The first output conductor portion 1e and the second output conductor portion 1f connected in parallel (in this case, two branches), the output elements 14a, 14b, 14c of the output side movable portion 13, and the output side conductor 51 Output elements 1e and 1f are alternately connected via insulator 5 It may be configured to so that.
That is, if the number of branches in one of the output side movable portion 13 and the output side conducting wire 1 connected via the insulator 5 is N, the number of other branches is preferably (N + 1).

Alternatively, although not shown (as shown in FIG. 2), the output side movable portion 13 has two first output elements 21 and second output elements 22 connected in parallel, and (as shown in FIG. 8). The output conductor 51 has two first output conductors 71 and second output conductors 72 connected in parallel. The output element of the output movable part 13 and the output element of the output conductor 51 However, you may comprise so that it may overlap alternately via an insulator.
That is, the number of branches of both the output side movable portion 13 and the output side conducting wire 1 is set to the same number N. In this case, the element located on the outermost side in the overlapping direction is preferably made smaller than the other elements.
In addition, the above-described configuration in which the number of branches (the number in parallel) is 2 or 3 or more is not limited to the output-side coupling portion Q between the output-side movable portion 13 and the output-side conductor 1, but the input-side conductor 2 The present invention can also be applied to the joint P with the input side base 11.

It is a perspective view which shows a part of distribution phase shifter (1st embodiment) of this invention. It is sectional drawing of the output side coupling | bond part which has the output side movable part and output side conducting wire of a movable coupling conductor. It is sectional drawing of the input side coupling | bond part which has the input side base of a movable coupling conductor, and an input side conductor. It is an equivalent circuit diagram of the coupling | bond part of an output side movable part and an output side conducting wire. It is sectional drawing which shows the modification of an output side movable part. It is sectional drawing of the input side coupling | bond part which has the input side base of a movable coupling conductor, and an input side conductor. It is sectional drawing of a distribution phase shifter. It is a perspective view which shows a part of distribution phase shifter (2nd embodiment) of this invention. It is sectional drawing of the coupling | bond part of an output side. It is a perspective view which shows a part of distribution phase shifter (3rd embodiment) of this invention. It is sectional drawing explaining the coupling | bond part of the input side of FIG. It is a perspective view which shows a part of distribution phase shifter (4th embodiment) of this invention. It is sectional drawing explaining the coupling | bond part of the output side of another form.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,51 Output side conducting wire 1a, 1b, 51a, 51b Output end 2,52 Input side conductor 3,53 Movable coupling conductor 4,54 Insulator 5,55 Insulator 6 Conductor axis (first terminal)
7 Input terminal part 9 Phase shifter body 11, 61 Input side base part 12, 62 Line part 13, 63 Output side movable part 13a, 13b Movable element 17 Upper conductor (outer conductor)
18 Lower conductor (outer conductor)
21 1st output element (1st output part)
22 Second output element (second output part)
23 3rd output element (3rd output part)
24 Fourth output element (fourth output section)
26 Tube conductor (second terminal)
31 First input element (first input conductor)
32 Second input element (second input conductor)
71 1st output conducting wire part 72 2nd output conducting wire part 81 1st input element (1st input base)
82 Second input element (second input base)
A Distributing phase shifter C Center line P Input side coupling part Q Output side coupling part

Claims (8)

An output side conductor whose end is the output end; and
An input conductor to which a high-frequency signal is input;
A movable coupling conductor for transmitting the high-frequency signal input to the input-side conductor to an output end of the output-side conductor;
With
The movable coupling conductor is movable along the output-side conductor and the input-side base coupled to the input-side conductor via an insulator, and coupled to the output-side conductor via the insulator. The output side movable part, and the line part electrically connecting the input side base part and the output side movable part,
The output-side movable unit includes a first output unit and a second output unit that are connected in parallel to the line unit and provided with the output-side conducting wire disposed therebetween. Phase shifter.   2. The phase shift according to claim 1, wherein the input-side conductor includes a first input conductor portion and a second input conductor portion that are connected in parallel and provided with the input-side base portion disposed therebetween. vessel.   2. The input side base portion includes a first input base portion and a second input base portion that are connected in parallel to the line portion and provided with the input side conductor disposed therebetween. Phase shifter.   The output side movable portion is connected in parallel to the line portion, and is opposed as a state in which the output side conductor is disposed in a direction perpendicular to the facing direction of the first output portion and the second output portion. The phase shifter as described in any one of Claims 1-3 which has the 3rd output part and 4th output part which are provided in this way. An input terminal portion having a first terminal connected to the input-side conductor, and a second terminal provided insulated from the first terminal;
A pair of plate-like outer conductors electrically connected to the second terminal and disposed opposite to each other,
5. The phase shifter body including the output-side conductor, the input-side conductor, and the movable coupling conductor is disposed at a substantially intermediate position between the pair of outer conductors. Phase shifter. The output-side conductor is an arc or a ring-shaped line with a part opened, and the input-side conductor is a conductor provided on a center line of the arc or a part-open ring, and The input side base of the movable coupling conductor is a rotationally symmetric conductor about the center line;
A conductor shaft connected to the input-side conductor and receiving a high-frequency signal and provided on the center line;
The input side base portion of the movable coupling conductor is attached to the conductor shaft via an insulator so as to be rotatable around a center line of the conductor shaft. Phase shifter. An output side conductor whose end is the output end; and
An input conductor to which a high-frequency signal is input;
A movable coupling conductor for transmitting the high-frequency signal input from the input-side conductor to an output end of the output-side conductor;
With
The movable coupling conductor is movable along the output-side conductor and the input-side base coupled to the input-side conductor via an insulator, and coupled to the output-side conductor via the insulator. The output side movable part, and the line part electrically connecting the input side base part and the output side movable part,
The output-side conducting wire has a first output conducting wire portion and a second output conducting wire portion that are connected in parallel and provided with the output-side movable portion disposed therebetween. vessel. An output side conductor whose end is the output end; and
An input conductor to which a high-frequency signal is input;
A movable coupling conductor for transmitting the high-frequency signal input to the input-side conductor to an output end of the output-side conductor;
With
The movable coupling conductor is movable along the output-side conductor and the input-side base coupled to the input-side conductor via an insulator, and coupled to the output-side conductor via the insulator. The output side movable part, and the line part electrically connecting the input side base part and the output side movable part,
The output side movable part has a cylindrical shape surrounding a part in the longitudinal direction of the output side conducting wire in the circumferential direction via the insulator.

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