JP6289290B2 - Antenna device - Google Patents

Description

  The present invention relates to an antenna device that can be used with two orthogonally polarized waves.

In recent years, with the advancement of information communication, the demand for higher functionality of antennas has increased, and antennas with wideband performance that operate well over a wide frequency range and orthogonal that can be used with two orthogonal polarizations. There is a need for antennas that share polarization.
For example, in Patent Documents 1 and 2 below, a non-excited element in a waveguide or a cavity is used as a cross-polarized antenna having good characteristics in a wide band or as a waveguide coupler for cross-polarization. The thing in which the metal flat plate called is arrange | positioned is disclosed.

When the antenna device equipped with this non-excitation element is used in outer space or the like, charges are accumulated in the non-excitation element that is a floating conductor, and the accumulated charges are directed toward the conductive waveguide wall. When discharged, this antenna device or an electronic device connected to the antenna device may be damaged. In order to prevent this, it is necessary to ground a non-excitation element which is a floating conductor to the waveguide.
Patent Document 3 below discloses a method of grounding a non-excitation element included in an antenna device by extending a conductor from the outer periphery of the non-excitation element and grounding the ground conductor at the end of the extended conductor. Has been.

FIG. 19 is a perspective view showing an antenna device disclosed in Patent Document 3. As shown in FIG.
The outline of this antenna apparatus will be described below.
The dielectric substrate 104 has a ground conductor plate 105 on the back surface, and the dielectric substrate 104 is installed on the conductor flat plate 106 through the ground conductor plate 105.
The excitation element 102 is formed on the dielectric substrate 104, and the non-excitation element 101 is disposed to face the excitation element 102. The excitation element 102 is fed by a feed line 103 parallel to the X direction.

When the straight line connecting the point where the feed line 103 is connected to the excitation element 102 and the center point of the excitation element 102 is parallel to the X direction, the main polarization component of the radio wave radiated or received by this antenna device Becomes polarized in the X direction.
The linear conductor 107 extends from the outer edge portion of the non-excitation element 101 in a direction (Y direction) perpendicular to the X direction, which is the main polarization direction of the antenna device, and is grounded to the conductor flat plate 106 at the ground point 108. Has been.
Thus, since the extending direction of the linear conductor 107 is orthogonal to the main polarization direction, the linear conductor 107 hardly interferes with the radio wave of the main polarization component. For this reason, the non-excitation element 101 can be grounded without impairing the electrical characteristics of the antenna device.

JP-A-2-223201 JP-A-6-67921 JP 2004-328067 A (FIG. 6)

  Since the conventional antenna device is configured as described above, the linear conductor 107 extends in a direction (Y direction) orthogonal to the X direction, which is the main polarization direction. For this reason, the linear conductor 107 hardly interferes with the radio wave of the main polarization component, but in addition to the feed line 103 parallel to the X direction, an orthogonal feed line parallel to the Y direction is provided. When applied to a polarization sharing antenna, the extension direction of the linear conductor 107 is parallel to the polarization direction in the Y direction. As a result, since the linear conductor 107 acts to interfere with radio waves polarized in parallel with the extension direction of the linear conductor 107, the electric power of the antenna device in the direction parallel to the extension direction of the linear conductor 107 is obtained. There was a problem that the target characteristics would be greatly impaired.

  The present invention has been made in order to solve the above-described problems, and an orthogonally polarized antenna capable of grounding a non-excitation element without incurring a large loss of electrical characteristics in two polarization directions. The object is to obtain a device.

  An antenna device according to the present invention includes a waveguide having one end short-circuited and the other end open, a plurality of feed probes inserted perpendicular to the tube axis of the waveguide, and a waveguide A conductor flat plate and a linear conductor connecting the waveguide and the conductor flat plate, a plurality of feeding probes are inserted so as to be orthogonal to each other, and the extension direction of the linear conductor is the feeding probe The linear conductors are arranged so as to be oblique to the feeding direction of the radio wave fed from to the waveguide.

  According to the present invention, the linear conductor is inserted such that the plurality of power feeding probes are orthogonal to each other, and the extending direction of the linear conductor is oblique to the feeding direction of the radio wave fed from the power feeding probe to the waveguide. Therefore, there is an effect that the conductive flat plate, which is a non-excitation element, can be grounded to the waveguide without causing a large loss of electrical characteristics in the two polarization directions.

It is a block diagram which shows the antenna apparatus by Embodiment 1 of this invention. It is explanatory drawing which shows the electric field distribution of the electromagnetic wave which propagates the inside of the waveguide 1, and the current distribution of the linear conductors 6a and 6b when the electromagnetic wave is supplied from the feeding probes 4a and 4b. It is a block diagram which shows the other antenna apparatus by Embodiment 1 of this invention. It is a block diagram which shows the other antenna apparatus by Embodiment 1 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 2 of this invention. It is explanatory drawing which shows the electric field distribution of the electromagnetic wave which propagates the inside of the waveguide 1, and the current distribution of the linear conductors 6a and 6b when the electromagnetic wave is supplied from the feeding probes 4a and 4b. It is a block diagram which shows the other antenna apparatus by Embodiment 2 of this invention. It is a block diagram which shows the other antenna apparatus by Embodiment 2 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 3 of this invention. It is explanatory drawing which shows the electric field distribution of the electromagnetic wave which propagates the inside of the waveguide 1, and the current distribution of the linear conductors 6a-6d when an electromagnetic wave is fed from the electric power feeding probes 4a-4d. It is a perspective view which shows the antenna apparatus by Embodiment 4 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 4 of this invention. It is a block diagram which shows the other antenna apparatus by Embodiment 4 of this invention. It is a block diagram which shows the other antenna apparatus by Embodiment 4 of this invention. It is a perspective view which shows the antenna apparatus by Embodiment 5 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 5 of this invention. It is a block diagram which shows the other antenna apparatus by Embodiment 5 of this invention. It is a block diagram which shows the other antenna apparatus by Embodiment 5 of this invention. FIG. 10 is a perspective view showing an antenna device disclosed in Patent Document 3.

Embodiment 1 FIG.
1 is a block diagram showing an antenna apparatus according to Embodiment 1 of the present invention.
1A is a top view seen from the antenna opening, FIG. 1B is a cross-sectional view taken along the line AA in FIG. 1A, and FIG. 1C is a cross-sectional view taken along the line BB in FIG. It is.
In FIG. 1, a waveguide 1 is a square waveguide having a square (rectangular) cross-sectional shape, one end of which is closed by a short-circuit conductor wall 2 made of a plate-like conductor and is electrically short-circuited. The end is open.
A feeding probe insertion hole 3a for inserting the feeding probe 4a perpendicular to the tube axis and a feeding probe for inserting the feeding probe 4b perpendicular to the tube axis are inserted into the tube wall of the waveguide 1. A hole 3b is provided.

The power supply probe 4 a is inserted into a power supply probe insertion hole 3 a provided on the tube wall of the waveguide 1.
The power supply probe 4 b is inserted into a power supply probe insertion hole 3 b provided on the tube wall of the waveguide 1. Thereby, the power feeding probe 4a and the power feeding probe 4b are inserted so as to be orthogonal to each other.
For example, since the center conductor of the coaxial line can be used as the power feeding probes 4a and 4b, the coaxial line may be inserted into the power feeding probe insertion holes 3a and 3b.

The conductor flat plate 5 is a conductor having a square (rectangular) cross-sectional shape, and the center of the conductor flat plate 5 is located on the tube axis of the waveguide 1. That is, the conductor flat plate 5 is disposed perpendicular to the tube axis of the waveguide 1 inside the waveguide 1 so that each side of the conductor flat plate 5 is parallel to each tube wall of the waveguide 1. Has been.
In the example of FIG. 1, the conductor flat plate 5 is disposed on the opening side of the waveguide 1 (upper side in FIGS. 1B and 1C) than the power feeding probes 4 a and 4 b, but from the power feeding probes 4 a and 4 b. May be arranged on the short-circuit conductor wall 2 side (lower side).
Further, the conductor flat plate 5 may be disposed at the opening of the waveguide 1 (the position of the upper end of the waveguide 1) or slightly above the opening.

The linear conductors 6a and 6b are linear conductors connecting the waveguide 1 and the conductor flat plate 5, and the extending direction of the linear conductors 6a and 6b is fed to the waveguide 1 from the feeding probes 4a and 4b. The linear conductors 6a and 6b are arranged so as to be oblique to the electric wave feeding direction.
That is, one end of the linear conductor 6a is connected to the corner of the conductor flat plate 5 (the upper right corner in the example of FIG. 1A), and the other end is the corner of the waveguide 1 (in the example of FIG. 1A). Connected to the upper right corner).
Further, one end of the linear conductor 6b is connected to a corner of the conductor flat plate 5 (lower right corner in the example of FIG. 1A), and the other end is a corner of the waveguide 1 (example of FIG. 1A). In the lower right corner).

Next, the operation will be described.
FIG. 2 is an explanatory diagram showing the electric field distribution of the radio wave propagating inside the waveguide 1 and the current distribution of the linear conductors 6a and 6b when the radio wave is supplied from the power supply probes 4a and 4b.
In particular, FIG. 2A shows a case where radio waves are supplied from the power supply probe 4a, and FIG. 2B shows a case where electric waves are supplied from the power supply probe 4b.

When a radio wave is fed from the power feeding probe 4a, the radio wave travels inside the waveguide 1 and is radiated from the opening of the waveguide 1 as shown in FIG.
The electric field distribution inside the waveguide 1 is mainly a so-called TE01 mode of the waveguide 1 and mainly has an electric field component parallel to the Y direction. That is, when a radio wave is fed from the feeding probe 4a, polarized waves parallel to the Y direction are radiated into the space.
At this time, since the conductor flat plate 5 is disposed so as to block the electric field inside the waveguide 1, parallel capacitive and inductive components are added to the input impedance of the feed probe 4a. As a result, it operates as a so-called resonance circuit, and impedance matching over a wide band is realized.

In addition, the linear conductors 6a and 6b shield the electric field inside the waveguide 1, but obliquely shield the electric field in the Y direction. The degree of influence on electrical characteristics is significantly reduced.
The electric field inside the waveguide 1 has a large amplitude at the central portion, and becomes a smaller amplitude as it approaches the tube walls parallel to the Y direction (upper and lower tube walls in FIG. 2). Therefore, the influence on the electrical characteristics by the linear conductors 6a and 6b in the portion close to the tube wall parallel to the Y direction is further reduced.

On the other hand, when a radio wave is fed from the feed probe 4b, the radio wave travels inside the waveguide 1 and is radiated from the opening of the waveguide 1 as shown in FIG. The electric field distribution inside 1 mainly has an electric field component parallel to the X direction. That is, when a radio wave is fed from the feeding probe 4b, polarized waves parallel to the X direction are radiated into the space.
At this time, the conductor flat plate 5 is arranged so as to block the electric field inside the waveguide 1 in the same manner as when the radio wave is fed from the feeding probe 4a, and therefore parallel to the input impedance of the feeding probe 4b. The capacitive and inductive components are added. As a result, it operates as a so-called resonance circuit, and impedance matching over a wide band is realized.

In addition, the linear conductors 6a and 6b shield the electric field inside the waveguide 1, but obliquely shield the electric field in the X direction. The degree of influence on electrical characteristics is significantly reduced.
Note that the electric field inside the waveguide 1 has a large amplitude at the central portion, and becomes a smaller amplitude as it approaches the tube walls parallel to the X direction (the right and left tube walls in FIG. 2). Therefore, the influence on the electrical characteristics by the linear conductors 6a and 6b in the portion close to the tube wall parallel to the X direction is further reduced.

As described above, the linear conductors 6a and 6b hinder both of the radio waves fed from the power feeding probes 4a and 4b, but have an influence on the electrical characteristics as compared with the case where they are shielded in parallel to the electric field direction. Since the degree is remarkably small, the electrical characteristics of the antenna device for both polarization directions are not greatly impaired.
Incidentally, when the radio waves fed from the power feeding probes 4a and 4b are obstructed obliquely, the degree of influence on the electrical characteristics is small, but when approaching parallel, the degree of influence on the electrical characteristics increases rapidly.

When a radio wave is fed from the feeding probe 4a, the electric field inside the waveguide 1 is hindered, so that the linear conductors 6a and 6b are inclined with respect to the Y direction as shown in FIG. Current flows.
At this time, since the linear conductors 6a and 6b are located on opposite sides of the feeding probe 4a, the X-direction component of the current flowing through the linear conductor 6a and the X-direction of the current flowing through the linear conductor 6b The components have substantially the same amplitude and are in opposite directions.
Therefore, among the radio waves generated by the current flowing through the linear conductors 6a and 6b and radiated to the space, the X-direction polarized waves corresponding to the cross-polarization components cancel each other, and the generation of the cross-polarization components occurs. It can be suppressed.

On the other hand, when a radio wave is fed from the feeding probe 4b, the electric field inside the waveguide 1 is hindered, so that the linear conductors 6a and 6b have no relation to the X direction as shown in FIG. An oblique current flows.
In this case, the Y direction component of the current flowing through the linear conductor 6a and the Y direction component of the current flowing through the linear conductor 6b have substantially the same amplitude and are in opposite directions.
Therefore, among the radio waves generated by the current flowing through the linear conductors 6a and 6b and radiated to the space, the Y-direction polarized waves corresponding to the cross-polarized wave components cancel each other, and the cross-polarized wave components are generated. It can be suppressed.
As described above, the linear conductors 6a and 6b generate cross polarization components orthogonal to the main polarization components of the radio waves fed from the power feeding probes 4a and 4b, but these cross polarization components cancel each other. No large cross polarization occurs in the front direction of the antenna.

  As apparent from the above, according to the first embodiment, the power feeding probes 4a and 4b are inserted so as to be orthogonal to each other, and the extending direction of the linear conductors 6a and 6b is changed from the power feeding probes 4a and 4b to the waveguide 1. Since the linear conductors 6a and 6b are arranged so as to be inclined with respect to the feeding direction of the radio wave fed to the antenna, non-excitation is caused without causing a large loss of electrical characteristics in the two polarization directions. The conductor flat plate 5 as an element can be grounded to the waveguide 1.

In the first embodiment, in FIG. 1A, the linear conductor 6a connects the upper right corner of the conductor flat plate 5 and the upper right corner of the waveguide 1, and the linear conductor 6b is the conductive flat plate 5. 1 is connected to the lower right corner of the waveguide 1. As shown in FIG. 3, the linear conductors 6 a and 6 b are connected to other conductor plates 5. You may make it connect between a corner | angular and the other corner of the waveguide 1. FIG.
In the example of FIG. 3A, the linear conductor 6a connects the lower left corner of the conductor flat plate 5 and the lower left corner of the waveguide 1, and the linear conductor 6b is the lower right corner of the conductive flat plate 5. And the lower right corner of the waveguide 1 are connected.
In the example of FIG. 3B, the linear conductor 6a connects the lower left corner of the conductor flat plate 5 and the lower left corner of the waveguide 1, and the linear conductor 6b is connected to the upper left corner of the conductive flat plate 5. The upper left corner of the waveguide 1 is connected.
In the example of FIG. 3C, the linear conductor 6 a connects between the upper right corner of the conductive plate 5 and the upper right corner of the waveguide 1, and the linear conductor 6 b is connected to the upper left corner of the conductive plate 5. The upper left corner of the waveguide 1 is connected.

  In the first embodiment, two linear conductors 6a and 6b with respect to two adjacent corners (both ends of one side of the conductive flat plate 5) among the four corners of the conductive flat plate 5. In the case where there is no request such as suppressing the size of the generated cross-polarized wave to a predetermined size, As shown in FIG. 4, one linear conductor 6 a may connect the corner of the conductor flat plate 5 and the corner of the waveguide 1. In this case as well, the conductor flat plate 5 that is a non-excitation element can be grounded to the waveguide 1 without causing a large loss of electrical characteristics in the two polarization directions.

  In the first embodiment, an example in which the cross-sectional shapes of the waveguide 1 and the conductor flat plate 5 are squares is shown, but the cross-sectional shapes of the waveguide 1 and the conductive flat plate 5 may be rectangular.

Embodiment 2. FIG.
5 is a block diagram showing an antenna apparatus according to Embodiment 2 of the present invention.
5A is a top view as seen from the antenna opening, FIG. 5B is a cross-sectional view taken along the line AA in FIG. 5A, and FIG. 5C is a cross-sectional view taken along the line BB in FIG. It is.
The second embodiment is different from the first embodiment in that the cross-sectional shapes of the waveguide 1 and the conductor flat plate 5 are circular.

A feeding probe insertion hole 3a for inserting the feeding probe 4a perpendicularly to the tube axis and a feeding probe 4b perpendicularly to the tube axis are inserted into the tube wall of the waveguide 1 having a circular cross section. The feed probe insertion hole 3b is provided, and the feed probe insertion hole 3a and the feed probe insertion hole 3b are orthogonal to each other. Therefore, the power feeding probe 4a and the power feeding probe 4b are inserted so as to be orthogonal to each other.
The angle formed between the extending direction of the linear conductors 6a and 6b and the feeding direction of the radio wave fed from the feeding probes 4a and 4b to the waveguide 1 is 45 degrees (or 135 degrees, 225 degrees, and 315 degrees). The linear conductors 6a and 6b are arranged so as to be.

Next, the operation will be described.
FIG. 6 is an explanatory diagram showing the electric field distribution of the radio wave propagating inside the waveguide 1 and the current distribution of the linear conductors 6a and 6b when the radio wave is fed from the power feeding probes 4a and 4b.
In particular, FIG. 6A shows a case where radio waves are supplied from the power supply probe 4a, and FIG. 6B shows a case where electric waves are supplied from the power supply probe 4b.

When a radio wave is supplied from the power supply probe 4a, the radio wave travels through the inside of the waveguide 1 and is radiated from the opening of the waveguide 1 as shown in FIG.
The electric field distribution inside the waveguide 1 is mainly a TE11 mode of a so-called circular waveguide, and mainly has an electric field component parallel to the Y direction in the vicinity of the center of the waveguide 1. That is, when a radio wave is fed from the feeding probe 4a, a polarized wave substantially parallel to the Y direction is radiated into the space.
At this time, since the conductor flat plate 5 is disposed so as to block the electric field inside the waveguide 1, parallel capacitive and inductive components are added to the input impedance of the feed probe 4a. As a result, it operates as a so-called resonance circuit, and impedance matching over a wide band is realized.

In addition, the linear conductors 6a and 6b shield the electric field inside the waveguide 1, but obliquely shield the electric field in the Y direction. The degree of influence on electrical characteristics is significantly reduced.
The electric field inside the waveguide 1 has a large amplitude at the center and a small amplitude at a position away from the center. Therefore, the influence on the electrical characteristics by the linear conductors 6a and 6b in the part away from the central part is further reduced.

On the other hand, when a radio wave is fed from the power feeding probe 4b, the radio wave travels inside the waveguide 1 and is radiated from the opening of the waveguide 1 as shown in FIG. The electric field distribution inside 1 mainly has an electric field component parallel to the X direction near the center of the waveguide 1. That is, when a radio wave is fed from the feeding probe 4b, a polarized wave substantially parallel to the X direction is radiated into the space.
At this time, the conductor flat plate 5 is arranged so as to block the electric field inside the waveguide 1 in the same manner as when the radio wave is fed from the feeding probe 4a, and therefore parallel to the input impedance of the feeding probe 4b. The capacitive and inductive components are added. As a result, it operates as a so-called resonance circuit, and impedance matching over a wide band is realized.

In addition, the linear conductors 6a and 6b shield the electric field inside the waveguide 1, but obliquely shield the electric field in the X direction. The degree of influence on electrical characteristics is significantly reduced.
The electric field inside the waveguide 1 has a large amplitude at the center and a small amplitude at a position away from the center. Therefore, the influence on the electrical characteristics by the linear conductors 6a and 6b in the portion close to the tube wall is further reduced.

As described above, the linear conductors 6a and 6b hinder both of the radio waves fed from the power feeding probes 4a and 4b, but have an influence on the electrical characteristics as compared with the case where they are shielded in parallel to the electric field direction. Since the degree is remarkably small, the electrical characteristics of the antenna device for both polarization directions are not greatly impaired.
Incidentally, when the radio waves fed from the power feeding probes 4a and 4b are obstructed obliquely, the degree of influence on the electrical characteristics is small, but when approaching parallel, the degree of influence on the electrical characteristics increases rapidly.

When a radio wave is fed from the feeding probe 4a, the electric field inside the waveguide 1 is hindered, so that the linear conductors 6a and 6b are inclined with respect to the Y direction as shown in FIG. Current flows.
At this time, since the linear conductors 6a and 6b are located on opposite sides of the feeding probe 4a, the X-direction component of the current flowing through the linear conductor 6a and the X-direction of the current flowing through the linear conductor 6b The components have substantially the same amplitude and are in opposite directions.
Therefore, among the radio waves generated by the current flowing through the linear conductors 6a and 6b and radiated to the space, the radio waves of the X-direction polarization corresponding to the cross-polarization component cancel each other in the Z-axis direction. Generation of wave components is suppressed.

On the other hand, when a radio wave is fed from the feeding probe 4b, the electric field inside the waveguide 1 is hindered, so that the linear conductors 6a and 6b have an X direction as shown in FIG. 6B. An oblique current flows.
In this case, the Y direction component of the current flowing through the linear conductor 6a and the Y direction component of the current flowing through the linear conductor 6b have substantially the same amplitude and are in opposite directions.
For this reason, among the radio waves generated by the current flowing through the linear conductors 6a and 6b and radiated into the space, the Y-direction polarized waves corresponding to the cross-polarization components are canceled out in the Z-axis direction, and the cross-polarization Generation of wave components is suppressed.
As described above, the linear conductors 6a and 6b generate a cross polarization component orthogonal to the main polarization component of the radio wave fed from the feed probes 4a and 4b, but the cross polarization component is canceled in the antenna front direction. , No large cross polarization occurs.

  As apparent from the above, even when the cross-sectional shapes of the waveguide 1 and the conductor flat plate 5 are circular, the power feeding probes 4a and 4b are inserted so as to be orthogonal to each other, and the extending direction of the linear conductors 6a and 6b is fed. Since the linear conductors 6a and 6b are arranged so as to be oblique to the feeding direction of the radio wave fed from the probes 4a and 4b to the waveguide 1, as in the first embodiment, 2 There is an effect that the conductor flat plate 5 which is a non-excitation element can be grounded to the waveguide 1 without causing a large loss of electrical characteristics in the two polarization directions.

  In the second embodiment, the angle formed between the extending direction of the linear conductors 6a and 6b and the feeding direction of the radio wave fed from the feeding probes 4a and 4b to the waveguide 1 is 45 degrees (or 135 degrees and 225 degrees). 315 degrees), the linear conductors 6a and 6b are shown. However, it is sufficient that the extending direction of the linear conductors 6a and 6b and the direction of feeding the radio wave are oblique. The angle may be an angle other than 45 degrees, 135 degrees, 225 degrees, and 315 degrees.

  In the second embodiment, in FIG. 5A, the linear conductor 6a and the linear conductor 6b sandwich the feeding probe 4a, and the gap between the outer peripheral portion of the conductor flat plate 5 and the inner peripheral portion of the waveguide 1. Although what is connected is shown, it is only necessary that the extending direction of the linear conductors 6a and 6b and the feeding direction of the radio wave are oblique, so that the linear conductors 6a and 6b and the feeding probe 4a are as shown in FIG. , 4b may be arranged.

  In the second embodiment, the two linear conductors 6a and 6b are shown. However, in the case where there is no request for suppressing the size of the generated cross polarization to a predetermined size. As shown in FIG. 8, one linear conductor 6 a may connect the outer peripheral portion of the conductor flat plate 5 and the inner peripheral portion of the waveguide 1. In this case as well, the conductor flat plate 5 that is a non-excitation element can be grounded to the waveguide 1 without causing a large loss of electrical characteristics in the two polarization directions.

In the example of FIG. 5, the conductor flat plate 5 is arranged on the opening side of the waveguide 1 (upper side in FIGS. 5B and 5C) than the power feeding probes 4 a and 4 b, but from the power feeding probes 4 a and 4 b. May be arranged on the short-circuit conductor wall 2 side (lower side).
Further, the conductor flat plate 5 may be disposed at the opening of the waveguide 1 (the position of the upper end of the waveguide 1) or slightly above the opening.

Embodiment 3 FIG.
FIG. 9 is a block diagram showing an antenna apparatus according to Embodiment 3 of the present invention.
9A is a top view as seen from the antenna opening, FIG. 9B is a cross-sectional view taken along the line AA in FIG. 9A, and FIG. 9C is a cross-sectional view taken along the line BB in FIG. It is. 9, the same reference numerals as those in FIG. 1 denote the same or corresponding parts.
In addition to the feed probe insertion holes 3a and 3b, a feed probe insertion hole 3c for inserting the feed probe 4c perpendicular to the tube axis and a feed probe 4d on the tube axis are provided on the tube wall of the waveguide 1. A feeding probe insertion hole 3d for vertical insertion is provided.

The power supply probe 4 c is inserted into a power supply probe insertion hole 3 c provided on the tube wall of the waveguide 1.
The power supply probe 4 d is inserted into a power supply probe insertion hole 3 d provided on the tube wall of the waveguide 1. Thereby, the power feeding probes 4a and 4c and the power feeding probes 4b and 4d are inserted so as to be orthogonal to each other.
For example, since the center conductor of the coaxial line can be used as the power supply probes 4a to 4d, the coaxial line may be inserted into the power supply probe insertion holes 3a to 3d.

The linear conductors 6c and 6d are linear conductors connecting the waveguide 1 and the conductor flat plate 5, and the linear conductors 6c and 6d are arranged so that the extending direction of the linear conductors 6c and 6d is oblique to the electric wave feeding direction. 6c and 6d are arranged.
That is, one end of the linear conductor 6c is connected to the corner of the conductor flat plate 5 (lower left corner in the example of FIG. 9A), and the other end is the corner of the waveguide 1 (in the example of FIG. 9A). , Lower left corner).
Further, one end of the linear conductor 6d is connected to a corner of the conductor flat plate 5 (upper left corner in the example of FIG. 9A), and the other end is a corner of the waveguide 1 (in the example of FIG. 9A). , Connected to the upper left corner).

Next, the operation will be described.
FIG. 10 is an explanatory diagram showing the electric field distribution of the radio wave propagating inside the waveguide 1 and the current distribution of the linear conductors 6a to 6d when the radio wave is supplied from the power supply probes 4a to 4d.
In particular, FIG. 10 (a) shows a case where radio waves of opposite phases are fed using the feed probes 4a and 4c, and FIG. 10 (b) shows that radio waves of opposite phases are fed using the feed probes 4b and 4d. A case where power is supplied is shown.

In the first and second embodiments, two feeding probes 4 a and 4 b that are orthogonal to each other and two linear conductors 6 a and 6 b are arranged. It has an asymmetric structure. For this reason, in addition to the main polarization component when the power feeding probes 4a and 4b are excited, not a few cross-polarization components are generated.
In the third embodiment, in order to suppress the generation of cross polarization components, four feeding probes 4a to 4d are inserted at positions symmetrical with respect to the tube axis of the waveguide 1, and four linear shapes are used. The conductors 6 a to 6 d are arranged at positions symmetrical with respect to the tube axis of the waveguide 1.

When radio waves are fed from the power feeding probes 4 a and 4 c, the radio waves travel through the inside of the waveguide 1 and are radiated from the opening of the waveguide 1 as shown in FIG.
The feeding probe 4a and the feeding probe 4c are fed with opposite-phase radio waves so that the radio wave fed from the feeding probe 4a and the radio wave fed from the feeding probe 4c are combined in phase within the waveguide 1. The
The electric field distribution inside the waveguide 1 mainly has electric field components parallel to the Y direction, and polarized waves parallel to the Y direction are radiated to the space.
At this time, although the linear conductors 6a to 6d block the electric field inside the waveguide 1, they are shielded obliquely with respect to the electric field in the Y direction, so that they are blocked in parallel with the electric field direction. The degree of influence on the electrical characteristics is significantly reduced.
The electric field inside the waveguide 1 has a large amplitude at the central portion, and becomes a small amplitude as it approaches the tube walls (upper and lower tube walls in FIG. 10) parallel to the Y direction. Therefore, the influence of the linear conductors 6a to 6d on the electrical characteristics in the portion close to the tube wall parallel to the Y direction is further reduced.

On the other hand, when radio waves are fed from the power feeding probes 4b and 4d, the radio waves travel through the inside of the waveguide 1 and are radiated from the opening of the waveguide 1 as shown in FIG.
The feeding probe 4b and the feeding probe 4d are fed with opposite-phase radio waves so that the radio wave fed from the feeding probe 4b and the radio wave fed from the feeding probe 4d are combined in phase within the waveguide 1. The
The electric field distribution inside the waveguide 1 mainly has electric field components parallel to the X direction, and polarized waves parallel to the X direction are radiated to the space.
At this time, the linear conductors 6a to 6d shield the electric field inside the waveguide 1, but obliquely shield the electric field in the X direction, so that they are shielded parallel to the electric field direction. The degree of influence on the electrical characteristics is significantly reduced.
The electric field inside the waveguide 1 has a large amplitude in the central portion, and becomes a small amplitude as it approaches the tube walls parallel to the X direction (the right and left tube walls in FIG. 10). Therefore, the influence on the electrical characteristics by the linear conductors 6a to 6d in the portion close to the tube wall parallel to the X direction is further reduced.

  As described above, the linear conductors 6a to 6d hinder radio waves fed from the power feeding probes 4a and 4c and radio waves fed from the power feeding probes 4b and 4d, but block them in parallel to the electric field direction. Since the influence on the electrical characteristics is remarkably small, the electrical characteristics of the antenna device for both polarization directions are not greatly impaired.

When radio waves are supplied from the power supply probes 4a and 4c, the electric field inside the waveguide 1 is prevented, so that the linear conductors 6a to 6d are connected to the Y direction as shown in FIG. An oblique current flows.
However, X-polarized radio waves generated by the current flowing through the linear conductors 6a to 6d and radiated into the space cancel each other due to the symmetry of the structure. Generation of wave components can be kept low.

On the other hand, when radio waves are fed from the feeding probes 4b and 4d, the electric field inside the waveguide 1 is prevented, and as shown in FIG. 10B, the linear conductors 6a to 6d are placed in the X direction. In contrast, an oblique current flows.
However, the Y-polarized radio waves generated by the current flowing through the linear conductors 6a to 6d and radiated into the space cancel each other due to the symmetry of the structure. Generation of wave components can be kept low.
As described above, the linear conductors 6a to 6d generate a cross polarization component orthogonal to the main polarization component of the radio wave fed by the power feeding probes 4a to 4d, but the cross polarization component is canceled due to the symmetry of the structure. Therefore, generation of cross polarization can be suppressed to a lower level.

  In the third embodiment, the example in which the cross-sectional shapes of the waveguide 1 and the conductor flat plate 5 are square (rectangular) is shown. However, as in the second embodiment, the cross-sections of the waveguide 1 and the conductive flat plate 5 are shown. A circular shape may be sufficient and the same effect can be acquired by arrange | positioning electric power feeding probe 4a-4d and the linear conductors 6a-6d symmetrically.

Embodiment 4 FIG.
FIG. 11 is a perspective view showing an antenna apparatus according to Embodiment 4 of the present invention, and FIG. 12 is a block diagram showing the antenna apparatus according to Embodiment 4 of the present invention.
12A is a top view as seen from the antenna opening, FIG. 12B is a cross-sectional view taken along the line AA in FIG. 12A, and FIG. 12C is a cross-sectional view taken along the line BB in FIG. It is. 11 and 12, the same reference numerals as those in FIG. 1 denote the same or corresponding parts.

In the antenna device of the fourth embodiment, a conductive chassis 7 having a through hole 7a having a rectangular cross section and a non-through hole 8a having the same shape as the through hole 7a of the conductive chassis 7 are provided. The waveguide 1 is composed of the chassis 8.
Further, the conductive chassis 7 and the conductive chassis 8 are electrically connected by a through hole 10 provided in the dielectric substrate 9.
The feed lines 11a and 11b (lines corresponding to the feed probes 4a and 4b in FIG. 1) are formed as strip conductors inside the dielectric substrate 9, and the conductor flat plate 5 and the linear conductors 6a and 6b are the surfaces of the dielectric substrate 9. Are formed as strip conductors.

The feed lines 11a and 11b have a structure in which a strip conductor is sandwiched between conductive walls of the conductive chassis 7 and 8, and form a so-called strip line.
The basic operation of the antenna device of the fourth embodiment is the same as that of the antenna device of the first embodiment due to the similarity in structure.
Further, since the conductor flat plate 5 and the linear conductors 6a and 6b are formed as strip conductors on the surface of the dielectric substrate 9, and the feed lines 11a and 11b are formed as strip conductors inside the dielectric substrate 9, This can be easily realized simply by processing the substrate.
Therefore, in the antenna device of the fourth embodiment, an antenna device having the same effect as that of the first embodiment can be obtained without being manufactured by a special manufacturing process.

In the fourth embodiment, the conductor flat plate 5, the linear conductors 6a and 6b, and the feed lines 11a and 11b are formed on the single dielectric substrate 9. However, as shown in FIG. The linear conductors 6a and 6b may be formed on the surface of the first dielectric substrate 9a, and the feed lines 11a and 11b may be formed inside the second dielectric substrate 9b.
Further, as shown in FIG. 14, the conductor flat plate 5 and the linear conductors 6a and 6b are formed on the surface of the first dielectric substrate 9a, and the feed line 11a is formed inside the second dielectric substrate 9b. The feed line 11b may be formed inside the third dielectric substrate 9c.
Note that the positional relationship between the dielectric substrates 9 shown in FIGS. 11 to 14 (the positional relationship between the conductor flat plate 5 and the feed lines 11a and 11b) is merely an example, and may be another positional relationship.

Embodiment 5. FIG.
FIG. 15 is a perspective view showing an antenna apparatus according to Embodiment 5 of the present invention, and FIG. 16 is a block diagram showing the antenna apparatus according to Embodiment 5 of the present invention.
16A is a top view seen from the antenna opening, FIG. 16B is a cross-sectional view taken along the line AA in FIG. 16A, and FIG. 16C is a cross-sectional view taken along the line BB in FIG. It is. 15 and 16, the same reference numerals as those in FIGS. 11 to 14 denote the same or corresponding parts.

In the antenna device of the fifth embodiment, the conductive chassis 7 having a through hole 7a having a rectangular cross section and the non-through hole 8a having the same shape as the through hole 7a of the conductive chassis 7 are provided. The waveguide 1 is composed of a chassis 8 and a conductive chassis 12 having a through hole 12 a having the same shape as the through hole 7 a of the conductive chassis 7.
The conductive chassis 7, the conductive chassis 8, and the conductive chassis 12 are electrically connected by through holes 10 provided in the dielectric substrates 9a and 9b.
The conductor flat plate 5 and the linear conductors 6a and 6b are formed as strip conductors on the surface of the first dielectric substrate 9a, and the feed lines 11a and 11b are formed as strip conductors on the surface of the second dielectric substrate 9b. .
Grooves 13 are formed in the conductive chassis 8 and 12 along the feed lines 11a and 11b. The feed lines 11a and 11b have a structure in which a strip conductor is sandwiched between grooves 13 provided in the conductive chassis 8 and 12, and form a so-called suspended strip line.

The basic operation of the antenna device of the fifth embodiment is the same as that of the antenna device of the first embodiment due to the similarity in structure.
The conductor flat plate 5 and the linear conductors 6a and 6b are formed as strip conductors on the surface of the first dielectric substrate 9a, and the feed lines 11a and 11b are formed as strip conductors on the surface of the second dielectric substrate 9b. Therefore, it can be easily realized only by performing normal substrate processing.
Therefore, in the antenna device of the fifth embodiment, an antenna device having the same effects as those of the first embodiment can be obtained without being manufactured by a special manufacturing process.

In the fifth embodiment, the dielectric substrate 9a on which the conductor flat plate 5 and the linear conductors 6a and 6b are formed and the dielectric substrate 9b on which the feed lines 11a and 11b are formed are shown separately. As shown in FIG. 17, the conductor flat plate 5, the linear conductors 6 a and 6 b and the feed lines 11 a and 11 b may be formed on a single dielectric substrate 9.
Further, as shown in FIG. 18, the conductor flat 5 and the linear conductor 6a, and 6b are formed on the surface of the first dielectric substrate 9a, to form a feed line 11a on the surface of the second dielectric substrate 9b, The feed line 11b may be formed on the surface of the third dielectric substrate 9c.
Note that the positional relationship between the dielectric substrates 9 shown in FIGS. 15 to 18 (the positional relationship between the conductor flat plate 5 and the feed lines 11a and 11b) is merely an example, and may be another positional relationship.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  1 Waveguide, 2 Short-circuit conductor wall, 3a, 3b, 3c, 3d Feed probe insertion hole, 4a, 4b, 4c, 4d Feed probe, 5 Conductor plate, 6a, 6b, 6c, 6d Linear conductor, 7 Conductivity Chassis, 7a through hole, 8 conductive chassis, 8a non-through hole, 9 dielectric substrate, 9a first dielectric substrate, 9b second dielectric substrate, 9c third dielectric substrate, 10 through hole, 11a, 11b Feed line, 12 Conductive chassis, 12a Through hole, 13 Groove, 101 Non-excitation element, 102 Excitation element, 103 Feed line, 104 Dielectric substrate, 105 Ground conductor plate, 106 Conductor plate, 107 Linear conductor, 108 Ground point.

Claims (12)

A waveguide with one end shorted and the other end open;
A plurality of feeding probes inserted perpendicular to the tube axis of the waveguide;
A conductor plate disposed inside the waveguide;
A linear conductor connecting the waveguide and the conductor plate,
The linear conductors are inserted so that the plurality of feeding probes are orthogonal to each other, and the extending direction of the linear conductors is oblique to the feeding direction of radio waves fed from the feeding probes to the waveguide. An antenna device characterized by being arranged.   The antenna device according to claim 1, wherein the waveguide and the conductor flat plate have a rectangular cross-sectional shape.   3. The antenna device according to claim 2, wherein the waveguide and the conductor flat plate have a square cross section.   The said conductor flat plate is arrange | positioned inside the said waveguide so that each edge | side of the said conductor flat plate and each tube wall of the said waveguide may become parallel, The Claim 2 or Claim characterized by the above-mentioned. 3. The antenna device according to 3.   5. The line conductor according to claim 2, wherein one end of the linear conductor is connected to a corner of the conductive plate and the other end is connected to a corner of the waveguide. The antenna device described. As the linear conductor connecting the waveguide and the conductor flat plate, comprising two linear conductors,
6. The antenna device according to claim 5, wherein one end of each of the two linear conductors is connected to two adjacent corners among four corners of the conductor flat plate. .   The antenna device according to claim 1, wherein the waveguide and the conductor flat plate have a circular cross-sectional shape.   8. The antenna device according to claim 7, wherein an angle formed between the feeding direction of the radio wave and the extending direction of the linear conductor is 45 degrees, 135 degrees, 225 degrees, or 315 degrees.   9. The antenna device according to claim 8, wherein two or four linear conductors extend toward the waveguide from different positions of the conductor flat plate.   10. The power feeding probe inserted perpendicularly to the tube axis of the waveguide has four power feeding probes inserted therein. 10. Antenna device.   The antenna device according to any one of claims 1 to 10, wherein the feeding probe is formed by a central conductor of a coaxial line. The said conductor flat plate, the said linear conductor, and the said electric power feeding probe are comprised by the strip conductor formed in the surface of a dielectric substrate, or an inside, The any one of Claims 1-10 characterized by the above-mentioned. The antenna device according to item.

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