JP7165394B2 - coaxial waveguide switch - Google Patents

Description

The present invention relates to coaxial waveguide switches.

In recent years, millimeter-wave radar devices that handle high-frequency signals in bands such as 76 GHz and 90 GHz have been put to practical use.
A millimeter-wave radar device includes, for example, a plurality of modules, and for transmission of high-frequency signals between the plurality of modules, for example, a coaxial cable assembly capable of transmitting high-frequency signals in a band of about 100 GHz is used. used. Here, the coaxial cable assembly means a coaxial cable with coaxial connectors connected to both ends thereof.

When testing such a module, for example, high-frequency signals output from a plurality of oscillators with different frequencies are switched and supplied to the input port of the module, and the high-frequency signals output from the output port of the module are switched to each other. It may be supplied by switching to a different detector.
Therefore, it is necessary to frequently switch the coaxial connector of the coaxial cable assembly between a plurality of oscillators and modules under test, or between a plurality of detectors and modules under test.
However, coaxial cables and coaxial connectors that handle high-frequency signals in bands such as 76 GHz and 90 GHz are constructed using extremely thin conductors, and therefore have low mechanical strength.
Therefore, if force is repeatedly applied to the coaxial connector and the coaxial cable by repeatedly attaching and detaching the coaxial connector, the coaxial connector of the module, the coaxial connector of the oscillator, the coaxial connector of the detector, the coaxial connector of the coaxial cable assembly, and the coaxial cable deteriorate. Doing so may cause damage.

Therefore, a coaxial switch for switching and transmitting a high-frequency signal input to one input port to a plurality of output ports is interposed between the module to be tested and the plurality of detectors, or a plurality of detectors are provided. It is conceivable to interpose a coaxial switch between a plurality of oscillators and a module to be tested, which switches a high-frequency signal input to an input port to a single output port for transmission.

JP 2007-251292 A

However, in the conventional coaxial switch, the upper limit of the high-frequency signal band that can be handled is about 10 GHz or 25 GHz due to its structure. However, the loss of high-frequency signals increases, making it difficult to use in practice.
Further, in the conventional waveguide switcher, switching one input port to either one of two output ports is limited, and one input port is switched to three or more output ports. It cannot be switched. Therefore, there is room for improvement in terms of improving usability of the waveguide switch.
The present invention has been made in view of the above circumstances, and its object is to suppress the loss of high-frequency signals even when the frequency band of the high-frequency signals to be transmitted is the high frequency band used in millimeter wave radar devices and the like. It is possible to switch and transmit high-frequency signals from a single supply source to a plurality of supply destinations while simultaneously transmitting high-frequency signals, or to switch and transmit high-frequency signals from a plurality of supply sources to a single supply destination. It is an object of the present invention to provide a coaxial waveguide switch that is advantageous for improvement.

In order to achieve the above object, the present invention provides a coaxial waveguide switch, wherein N is an integer of 2 or more, and a waveguide switch capable of switching one input port to N output ports. a coaxial waveguide converter attached to the input port; and horn antennas attached to the output ports, respectively , wherein the waveguide switch includes a pair of side walls facing each other. , the input port is formed on one of the pair of side walls, and the N output ports are formed on the other side wall of the pair of side walls at intervals in a direction orthogonal to the direction in which the pair of side walls face each other. and a moving body is provided between the pair of side walls so as to be movable in the orthogonal direction, and a motor is provided to stopably move the moving body to the N stop positions spaced apart in the orthogonal direction. wherein the moving body is formed with N waveguides selectively connected to the input port and the N output ports at each of the N stop positions. characterized by
Further, according to the present invention, the moving body includes a first member and a second member that are superimposed and attached to each other, and the cross section of the N waveguides is the same as that of the first member. A mating surface on which the first member is superimposed on the second member, and a mating surface on which the second member is superimposed on the first member. is formed with concave grooves forming half portions of the N waveguides in the height direction, and the first member and the second member are superimposed and attached to each other. It is characterized in that the grooves on the mating surface of the first member and the grooves on the mating surface of the second member constitute the N waveguides.
Further , according to the present invention, each of the N waveguides is provided with a filter for selectively passing an electromagnetic wave of a predetermined wavelength, and the wavelengths of the electromagnetic wave passed by each filter are different from each other. It is characterized by

According to the present invention, even if the frequency band of a high-frequency signal transmitted via a coaxial cable is a high frequency band used in a millimeter-wave radar device or the like, a single coaxial connector can be used while suppressing the loss of the high-frequency signal. A high-frequency signal input to the antenna can be switched and transmitted to a plurality of horn antennas, which is advantageous in terms of improving usability.
According to the present invention, the moving body is moved to N (N≧2) stop positions by driving the motor, and the N waveguides of the moving body are connected to the N waveguides of the moving body. At each of the stop positions, the N waveguides are selectively connected to the input port and the N output ports. Therefore, a high-frequency signal input to one input port can be switched and transmitted to N output ports, which is advantageous in improving usability.
The present invention is advantageous in ensuring accurate formation of N waveguides.
According to the present invention, electromagnetic waves having different wavelengths can be output from each horn antenna by a simple configuration in which filters are provided in N waveguides.

FIG. 4A is an explanatory diagram of the coaxial waveguide switch according to the embodiment, and a plan view of the coaxial waveguide switch with the upper cover removed, FIG. (B) shows the state in which the moving body is located at the second stop position, and (C) shows the state in which the moving body is located at the third stop position. (A) is a perspective view of a coaxial waveguide converter, and (B) is a side view of the coaxial waveguide converter. (A) is a perspective view of a horn antenna, and (B) is a side view of the horn antenna. FIG. 4 is a front view of the coaxial waveguide switch with the side walls for input ports removed; FIG. 5 is a cross-sectional view taken along line XX of FIG. 4 and shows a state in which the side wall for input port is attached. (A) is a plan view of the base, and (B) is a view in the direction of arrow B of (A). (A) is a plan view of the lower member, (B) is a view on arrow B of (A), and (C) is a view on arrow C of (A). (A) is a plan view of the upper member, and (B) is a B arrow view of (A). It is the figure which looked at the input port side wall part from the front. It is the figure which looked at the output port side wall part from the back. FIG. 10 is an explanatory diagram of the coaxial waveguide switch according to the modification, and is a plan view of the coaxial waveguide switch with the upper cover removed, showing a state in which the moving body is positioned at the first stop position;

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings.
As shown in FIGS. 1A, 2A, 2B, 3A, and 3B, the coaxial waveguide switch 100 includes the waveguide switch 10 and one coaxial It comprises a waveguide converter 60 and three horn antennas (electromagnetic horns) 70 .
As shown in FIGS. 1A, 4, and 5, the waveguide switch 10 includes a case 12, a base 14, a moving body 16, and a motor 18. As shown in FIG.
The case 12 includes a lower cover 20 , an input port sidewall 22 , an output port sidewall 24 , a pair of end walls 26 and 28 and an upper cover 30 .
The lower cover 20 has a rectangular plate shape.
The input port side wall 22 and the output port side wall 24 stand upright from a pair of long sides of the lower cover 20, are parallel to each other, and have a rectangular plate shape.
A pair of end walls 26 and 28 rise from a pair of short sides of the lower cover 20, are parallel to each other, and are positioned between both ends of the input port side wall 22 and the output port side wall 24. is doing.
The upper cover 30 is formed of a rectangular plate having the same shape and size as the lower cover 20, and connects the upper portions of the input port side wall 22, the output port side wall 24, and the pair of end walls 26, 28. As shown in FIG.

As shown in FIG. 9, a single input port 32 is formed at the longitudinal center and upper portion of the input port side wall 22 .
The input port 32 includes a vertically elongated rectangular opening 3202 and a plurality of screw holes 3204 formed around the opening 3202 .
As shown in FIG. 10, three output ports 34, 36, and 38, namely, first, second, and third, are arranged at equal intervals in the longitudinal direction of the output port side wall 24 on the upper portion of the output port side wall 24. formed. The middle first output port 36 of the first, second and third output ports 34 , 36 , 38 is located in the longitudinal center of the output port side wall 24 .
The first, second, and third output ports 34, 36, 38 have vertically elongated rectangular openings 3402, 3602, 3802 and a plurality of threaded holes 3404 formed around the openings 3402, 3602, 3802. , 3604 and 3804.
As shown in FIGS. 1A to 1C and 5, an annular choke is provided on the inner surface of the input port side wall 22 facing the side surface of the moving body 16 so as to surround the opening 3202 of the input port 32. A groove 3210 is formed. In addition, on the inner surface of the output port side wall 24 facing the side surface of the moving body 16, an annular shape is formed so as to surround each opening 3402, 3602, 3802 of the first, second and third output ports 34, 36, 38. Choke grooves 3410, 3610 and 3810 are formed respectively.
These choke grooves 3210, 3410, 3610, and 3810 fill the gap between the inner surface of the input port side wall 22 and the side surface of the moving body 16 and the gap between the inner surface of the output port side wall 24 and the side surface of the moving body 16. It is intended to suppress the loss of the high-frequency signal caused by this.

As shown in FIGS. 1A, 4 and 5, the base 14 is positioned above the lower cover 20 between the input port side wall 22, the output port side wall 24, and the pair of end walls 26, 28. and has a rectangular shape in plan view.
As shown in FIG. 6, the upper portion of the base 14 is provided with a first recessed portion 1402 extending longitudinally through the base 14 at the center portion in the width direction. A shallower depth second recess 1404 is provided.

As shown in FIGS. 5, 7A, 7B, 8C, 8A and 8B, the moving body 16 includes a lower member (first member) 40 and the lower member 40 The lower member 40 and the upper member 42 are both rectangular in plan view.
A projecting portion 4002 is provided at the center of the lower portion of the lower member 40 .
A female thread 41 is formed in the projecting portion 4002 so as to extend in the longitudinal direction of the lower member 40 .
The projecting portion 4002 is continuous in the longitudinal direction of the lower member 40 , and both sides of the projecting portion 4002 in the width direction are the lower surfaces 4004 of the lower member 40 . A bearing 44 is attached to the lower surface 4004 .
The lower member 40 is movably arranged on the base 14 via a bearing 44 that slides on the second recess 1404 .
That is, the protrusion 4002 is housed in the first recess 1402 and the bearing 44 contacts the second recess 1404, so that the lower member 40 is slidably arranged on the base 14. As shown in FIG.

As shown in FIGS. 1A and 4, the lower member 40 is moved by driving the motor 18 attached to the end wall 28 via a bracket 46. As shown in FIG. In this embodiment, the motor 18 is a stepping motor.
That is, the output shaft 1802 of the motor 18 and the ball screw 48 are connected through the coupling 50 inside the bracket 46, and the ball screw 48 is rotatably supported by the end wall 28 through the bearing 51. 48 is screwed into the internal thread 41 (see FIG. 5) of the projecting portion 4002 .

As shown in FIGS. 1A, 4, 5, 7A, 7B, 8C, 8A and 8B, the upper surface (mating surface) 4006 of the lower member 40 and the lower surface (mating surface) 4202 of the upper member 42 are provided with three grooves 52A, 52B, 54A, 54B, 56A, and 56B spaced apart in the longitudinal direction of the lower member 40 and the upper member 42, respectively. ing. Each recessed groove 52A, 52B, 54A, 54B, 56A, 56B constitutes a half portion of each waveguide 52, 54, 56 in the height direction.
The first groove 52A provided in the center of the longitudinal direction of the upper surface 4006 of the lower member 40 and the first groove 52B provided in the center of the lower surface 4202 of the upper member 42 in the longitudinal direction are connected to the lower member 40, It extends linearly in a direction parallel to the short sides of the rectangle of the upper member 42 .

Second and third grooves 54A and 56A provided on both longitudinal sides of the upper surface 4006 of the lower member 40 and second and third grooves 54B provided on both longitudinal sides of the lower surface 4202 of the upper member 42 . , 56B are first straight portions 5402A, 5602A, 5402B, 5602B parallel to the first grooves 52A, 52B on the side of the input port 32, and the first straight portions 5402A, 5602A, 5402B, 5602B to the first groove 52A. , 52B, and second linear portions 5406A, 5606A, 5406B, 5606B parallel to the first concave grooves 52A, 52B on the output ports 34, 36, 38 side. have.

The lower member 40 and the upper member 42 are attached by a plurality of screws, and as shown in FIGS. The first waveguide 52 is formed by the groove 52B, and the second waveguide 54 is formed by the second groove 54A of the lower member 40 and the second groove 54B of the upper member 42. and the third groove 56B of the upper member 42 form the third waveguide 56. As shown in FIG.
Thus, the upper surface 4006 of the lower member 40 is provided with the first groove 52A, the second groove 54A, and the third groove 56A, and the lower surface 4202 of the upper member 42 is provided with the first groove 52B and the second groove 54B. Since the first to third waveguides 52, 54, 56 are formed by providing the third concave groove 56B, the first to third waveguides 52, 54, 56 can be reliably formed. This is advantageous for accurate formation.

As shown in FIG. 1A, on the side surface of the lower member 40 and the side surface of the upper member 42 located on the input port 32 side, that is, the side surface of the moving body 16, an input opening 5210 of the first waveguide 52 is provided. , the input opening 5410 of the second waveguide 54 and the input opening 5610 of the third waveguide 56 are located.
In addition, on the side surface of the lower member 40 and the side surface of the upper member 42 located on the side of the output ports 34, 36, 38, that is, the side surface of the moving body 16, the output opening 5212 of the first waveguide 52 and the second waveguide are provided. The output opening 5412 of the waveguide 54 and the output opening 5612 of the third waveguide 56 are located.
In the moving body 16, the side surfaces of the lower member 40 and the upper member 42 movably contact the inner surfaces of the input port side wall 22 and the output port side wall 24, and the upper surface of the upper member 42 moves to the lower surface of the upper cover 30. contact as possible.

As shown in FIG. 1A, a coaxial waveguide transformer 60 is attached to input port 32 .
The coaxial waveguide converter 60 mutually converts a coaxial transmission line formed by a coaxial cable and a waveguide transmission line formed by a waveguide.
As shown in FIG. 2, the coaxial waveguide converter 60 includes a flange 62, an opening 64, a plurality of screw insertion holes 66, and a coaxial connector 68. As shown in FIG.
The flange 62 has a rectangular plate shape, and in this embodiment, has a square plate shape, but the shape of the flange 62 may be a rectangular plate shape, a disk shape, or any other conventionally known shape. .
The opening 64 is formed through the center of the flange 62 and has the same rectangular shape as the opening 3202 of the input port 32 .
A plurality of threaded holes 66 are formed around opening 64 and correspond to respective threaded holes 3204 of input port 32 .
A coaxial connector 68 protrudes from the center of one surface of the flange 62 in the thickness direction and is detachably connected to a coaxial connector provided at the end of the coaxial cable.
In this embodiment, the coaxial connector 68 protrudes linearly from one surface of the flange 62 in the thickness direction. It is possible to employ various conventionally known structures such as

Attachment of the coaxial waveguide transformer 60 to the input port 32 is done as follows.
That is, the flange 62 of the coaxial waveguide converter 60 is overlaid on the input port side wall 22 .
The longitudinal direction of the opening 64 of the coaxial waveguide converter 60 coincides with the longitudinal direction of the opening 3202 of the input port 32, and the screw insertion hole 66 of the coaxial waveguide converter 60 is aligned with the input port 32 aligned with each screw hole 3204 of the .
Next, the coaxial waveguide converter 60 is attached to the input port 32 by fastening the screws inserted through the screw insertion holes 66 of the coaxial waveguide converter 60 to the respective screw holes 3204 .
The coaxial waveguide converter 60 attached to the input port 32 is hereinafter referred to as an input port side coaxial waveguide converter 60A.

As shown in FIG. 1A, horn antennas 70 are attached to the first, second and third output ports 34, 36 and 38, respectively.
The horn antenna 70 radiates (transmits) into space an electromagnetic wave transmitted from a waveguide transmission line composed of a waveguide, or receives an electromagnetic wave radiated into space and transmits it to the waveguide transmission line. It is something to do.
As shown in FIG. 3 , the horn antenna 70 includes a flange 72 , an opening 74 , a plurality of screw insertion holes 76 and a horn portion 78 .
The flange 72 has a rectangular plate shape, and in this embodiment, has a square plate shape, but the shape of the flange 72 may be a rectangular plate shape, a disk shape, or any other conventionally known shape. .
An opening 74 is formed through the center of the flange 72 and has the same rectangular shape as the openings 3402 , 3602 , 3802 of the first, second, and third output ports 34 , 36 , 38 .
A plurality of screw holes 76 are formed around the opening 74 and correspond to the screw holes 3404, 3604, 3804 of the first, second and third output ports 34, 36, 38, respectively.
The horn portion 78 is formed of a pyramid-shaped wall portion that protrudes from the center of one surface of the flange 62 in the thickness direction and widens as the distance from the flange 62 increases.
An opening formed at the tip edge of the horn portion 78 constitutes a radio wave radiation surface 80 of the horn antenna 70, from which electromagnetic waves are radiated or received.
In the present embodiment, the case where the horn portion 78 has a pyramidal shape will be described, but the horn portion 78 may have a conical shape, and various conventionally known structures can be employed as the horn portion 78 .

Attachment of the horn antenna 70 to the first, second and third output ports 34, 36, 38 is as follows.
That is, the flange 72 of the horn antenna 70 is overlaid on the output port side wall 24 .
The longitudinal direction of the aperture 74 of the horn antenna 70 matches the longitudinal direction of the apertures 3402, 3602 and 3802 of the first, second and third output ports 34, 36 and 38, and the horn antenna 70 are aligned with the screw holes 3404, 3604, 3804 of the first, second and third output ports 34, 36, 38, respectively.
Next, screws inserted through the respective screw insertion holes 76 of the horn antenna 70 are fastened to the respective screw holes 3404, 3604, 3804, whereby the first, second and third output ports 34, 36, 38 of the respective horn antennas 70 are connected. attached to.
The horn antennas 70 attached to the first, second and third output ports 34, 36 and 38 are hereinafter referred to as first to third output port side horn antennas 70A, 70B and 70C.

Next, the effects of the coaxial waveguide switch 100 will be described.
As shown in FIG. 1A, the input port 32 is aligned with the input opening 5210 of the first waveguide 52 by driving the motor 18, and the output opening 5212 of the first waveguide 52 and the first waveguide 52 are aligned. , and the input port 32 and the first output port 34 are connected by a first waveguide 52 to form a first stop position for the vehicle 16 .
Further, as shown in FIG. 1B, the input port 32 and the input opening 5410 of the second waveguide 54 are aligned by driving the motor 18, and the output opening 5412 of the second waveguide and the second waveguide 5412 are aligned. Two output ports 36 are mated to form a second stop position for the vehicle 16 where the input port 32 and the second output port 36 are connected by a second waveguide 54 .
Further, as shown in FIG. 1(C), the input port 32 and the input opening 5610 of the third waveguide 56 are aligned by driving the motor 18, and the output opening 5612 of the third waveguide 56 is aligned. A third stop position of the vehicle 16 is formed where the third output port 38 is aligned and the input port 32 and the third output port 38 are connected by a third waveguide 56 .
That is, by driving the motor 18, the moving body 16 is moved to three stop positions spaced apart in a direction perpendicular to the direction in which the input port side wall 22 and the output port side wall 24 face each other.
The first to third waveguides 52, 54, 56 of the moving body 16 are connected to the input port 32, the first to third output ports 34, 36, 38 are selectively connected.

The control for stopping the moving body 16 at the first to third stop positions is performed by controlling the drive signal of the motor 18 to control the amount of movement of the moving body 16 .
Further, in the present embodiment, the case where the motor 18 is a stepping motor has been described, but a servomotor that performs rotation control by feedback control may be used as the motor 18 .
Further, first to third limit switches are provided for detecting first to third stop positions of the moving body 16, respectively, and the rotation of the motor 18 is controlled according to the detected states of these three limit switches. , various conventionally known control methods can be used.

Next, a case will be described in which the high-frequency signal output from the supply source is switched and supplied to the first to third external devices via the coaxial waveguide switch 100 .
For example, when a high-frequency signal supplied from a module to be tested in a millimeter-wave radar device is selected and supplied to three detectors, the module corresponds to the supply source, and the three detectors are the first to third detectors. It corresponds to the external device (supply destination) of
In order to connect the module (supply source) and the coaxial waveguide converter 60, a coaxial cable assembly having coaxial connectors connected to both ends of the coaxial cable is prepared in advance.

The coaxial connector 68 of the input port side coaxial waveguide converter 60A of the coaxial waveguide switch 100 and the coaxial connector of the supply source are connected via a coaxial cable assembly.
Further, the first to third external devices are provided with first to third external device side horn antennas corresponding to the first to third output port side horn antennas 70A, 70B and 70C. The to third external device side horn antennas are connected to the waveguides of the first to third external devices.
More specifically, the radio wave radiation surface 80 of the first output port side horn antenna 70A and the electromagnetic radiation surface of the first external device side horn antenna face each other across a space, and electromagnetic waves are transmitted and received between these horn antennas. Positioning of the first output port side horn antenna 70A and the first external device side horn antenna is performed.
The radio wave radiation surface 80 of the second output port side horn antenna 70B and the electromagnetic radiation surface of the second external device side horn antenna are opposed to each other with a space therebetween so that electromagnetic waves are transmitted and received between the horn antennas. The second output port side horn antenna 70B and the second external device side horn antenna are positioned.
The radio wave radiation surface 80 of the third output port side horn antenna 70C and the electromagnetic radiation surface of the third external device side horn antenna face each other with a space therebetween so that electromagnetic waves can be transmitted and received between these horn antennas. The third output port side horn antenna 70C and the third external device side horn antenna are positioned.

When the moving body 16 is stopped at the first stop position by controlling the rotation of the stepping motor 18 as shown in FIG. The high frequency signal (electromagnetic waves) supplied to the converter 60A is transmitted to the first output port 34 via the input port 32 and the first waveguide 52, and is transmitted to the first output port side horn antenna 70A and the first is supplied to the first external device via the external device side horn antenna.
When the moving body 16 is stopped at the second stop position by controlling the rotation of the stepping motor 18 as shown in FIG. The high frequency signal (electromagnetic wave) supplied to the converter 60A is transmitted to the second output port 36 via the input port 32 and the second waveguide 54, and is transmitted to the second output port side horn antenna 70B and the second is supplied to the second external device via the horn antenna on the external device side.
When the moving body 16 is stopped at the third stop position by controlling the rotation of the stepping motor 18 as shown in FIG. The high frequency signal supplied to the converter 60A is transmitted to the third output port 38 via the input port 32 and the third waveguide 56, and is transmitted to the third output port side horn antenna 70C and the third external device. It is fed to a third external device via a side horn antenna.

According to the coaxial waveguide switch 100 of the present embodiment, even if the frequency band of the high frequency signal transmitted via the coaxial cable is a high frequency band used in a millimeter wave radar device or the like, the high frequency signal High-frequency signals input to the coaxial connector 68 of one input port side coaxial waveguide converter 60A are switched to the first, second, and third output port side horn antennas 70A, 70B, and 70C while suppressing loss. It is possible to transmit the data through space, which is advantageous in terms of improving usability.

It goes without saying that in the present invention, the input port of the present invention may be used as the output port and the output port of the present invention may be used as the input port. In this case, the waveguide switch 10 has N input ports switchable to one output port, where N is an integer of 2 or more.
That is, in this embodiment, the waveguide switch 10 has one input port 32, first, second and third output ports 34, 36 and 38, and one input port side coaxial waveguide. A case has been described in which high frequency signals (electromagnetic waves) input to the coaxial connector 68 of the wave tube converter 60A are switched to be transmitted to the first, second and third output port side horn antennas 70A, 70B and 70C.
In other words, one supply source is connected to the input port side coaxial waveguide converter 60A via the coaxial cable assembly, and the first to third external devices (supply destinations) are connected to the first, second, and third devices. 3 output port side horn antennas 70A, 70B, and 70C.
However, the transmission direction of the high-frequency signal may be opposite to that in the embodiment.
In that case, the waveguide switch 10 would have first, second and third input ports 34 , 36 , 38 and one output port 32 .
In this case, the coaxial waveguide switch 100 includes first, second and third input port side coaxial waveguide converters connected to the first, second and third input ports 34 , 36 and 38 . and one output port side horn antenna connected to the output port 32 .
Then, the first to third supply sources are connected to the first, second, and third input port side coaxial waveguide converters via coaxial cable assemblies, respectively, and one external device is connected to one external device. The connection can be made via the horn antenna on the output port side.
For example, when the coaxial waveguide switch 100 is used to select and supply high-frequency signals from three oscillators to a module to be tested in a millimeter-wave radar device, the three oscillators are the first to third oscillators. It corresponds to the third supply source, and the module corresponds to the supply destination.
Of course, in such a case, the same effects as those of the embodiment can be obtained.

Next, a modified example of the embodiment will be described with reference to FIG.
As shown in FIG. 11, in the modified example, first and second waveguides 52, 54 and 56 selectively pass electromagnetic waves of predetermined wavelengths, respectively. , and third filters 82A-82C.
The wavelengths of the electromagnetic waves passed through the first, second and third filters 82A-82C are set to different values.
According to such a modification, the coaxial waveguide switch 100 is provided with first, second, and third filters 82A to 82C in a simple configuration, and electromagnetic waves output from a single supply source are combined with each other. Three electromagnetic waves with different wavelengths can be supplied to each external device (supply destination) via the first, second and third output port side horn antennas 70A, 70B and 70C.
Therefore, there is no need to provide a supply source for each wavelength, and a single supply source is sufficient, which is advantageous in terms of reducing the labor and cost required for testing external devices (modules).

10 Waveguide Switch 12 Case 16 Moving Body 18 Motor 22 Input Port Side Wall 24 Output Port Side Walls 26 , 28 End Wall 32 Input Port 34 First Output Port 36 Second Output Port 38 Third Output Port 40 Lower member (first member)
4006 upper surface (mating surface)
42 upper member (second member)
4202 lower surface (mating surface)
52 First waveguide 54 Second waveguide 56 Third waveguide 52A, 52B First grooves 54A, 54B Second grooves 56A, 56B Third grooves 60 Coaxial waveguide converter 70 Horn antenna 82A First filter 82B Second filter 82C Third filter 100 Coaxial waveguide switch

Claims (3)

a waveguide switcher capable of switching one input port to N output ports, where N is an integer of 2 or more;
a coaxial waveguide transformer attached to the input port;
and horn antennas respectively attached to the output ports,
The waveguide switch is
comprising a pair of side walls facing each other;
the input port is formed in one of the pair of side walls;
the N output ports are formed on the other side wall of the pair of side walls at intervals in a direction orthogonal to the direction in which the pair of side walls face each other;
A movable body is provided between the pair of side walls so as to be movable in the orthogonal direction;
providing a motor for moving the moving body to the N stop positions spaced apart in the orthogonal direction so as to be able to stop;
N waveguides selectively connected to the input port and the N output ports are formed in the moving body at each of the N stop positions,
A coaxial waveguide switch characterized by: the moving body includes a first member and a second member that are superimposed and attached to each other;
the cross section of the N waveguides has a height in the direction in which the first member and the second member are superimposed;
A mating surface where the first member is overlaid on the second member and a mating surface where the second member is overlaid on the first member have half of the height direction of the N waveguides. concave grooves forming parts are respectively formed,
When the first member and the second member are superimposed and attached, the N waveguides are formed by the grooves on the mating surfaces of the first member and the grooves on the mating surface of the second member. roads are constructed
2. The coaxial waveguide switch according to claim 1 , wherein: each of the N waveguides is provided with a filter that selectively passes an electromagnetic wave of a predetermined wavelength;
The wavelengths of the electromagnetic waves that pass through each filter are different values,
3. The coaxial waveguide switch according to claim 1 , wherein:

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