JP2017028429A - Antenna device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an antenna device capable of reducing sidelobe in a ground direction without causing gains in a radio wave radiation direction to be reduced.SOLUTION: An antenna device includes a cylindrical wall surface 2a arranged around an array antenna. On the cylindrical wall surface 2a, a reflection surface for reflecting radio waves reflected from the array antenna or a structure 2 acting as a transmission surface for transmitting the radio waves therethrough are provided. By a control part 5, out of the wall surface 2a possessed by the structure 2, the wall surface 2a in a sight range from the array antenna in the ground direction is set in the reflection surface and the wall surface 2a out of the sight range in the ground direction is set in the transmission surface.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an antenna device applied to a radar mounted on a flying object such as an aircraft.

The antenna device disclosed in the following Patent Document 1 includes a beam-variable planar antenna and two reflecting surfaces that can switch between reflection and transmission of radio waves radiated from the beam-variable planar antenna. ing.
In general, a beam-variable planar antenna has a characteristic that the gain is high in the vertical direction and the gain is low in the lateral direction, which is a direction orthogonal to the vertical direction.

In this antenna apparatus, in order to obtain a high gain even in the lateral direction, two reflecting surfaces are arranged obliquely in front of a beam-variable planar antenna.
That is, the first reflecting surface is arranged diagonally to the left of the planar antenna, and the second reflecting surface is arranged diagonally to the right of the planar antenna.
Thereby, for example, when the first reflecting surface arranged diagonally left front is set in a radio wave reflecting state, and the second reflecting surface arranged diagonally forward right is set in a radio wave transmitting state, the beam is variable. The radio wave radiated from the planar antenna is reflected by the first reflecting surface arranged diagonally to the left and travels in the direction of the second reflecting surface arranged diagonally forward to the right. The light passes through the second reflecting surface disposed obliquely forward.
Thereby, even when radio waves are radiated in the right direction, which is the horizontal direction, a high gain can be obtained.

When this antenna device is mounted on an aircraft, the aircraft often flies in a horizontal direction with respect to the ground. Therefore, in general, the beam is variable so that the vertical direction with a high gain is directed in the horizontal direction. A planar antenna is arranged.
In this case, the second reflecting surface is arranged in the ground direction, and the first reflecting surface is arranged in the sky direction.
Therefore, under the condition of searching for an object or the like that exists in the ground direction, the first reflecting surface is set in the radio wave reflecting state, and the second reflecting surface is set in the radio wave transmitting state.

Japanese Patent Laying-Open No. 2013-70366 (FIG. 1)

  Since the conventional antenna apparatus is configured as described above, after being radiated from the beam-variable planar antenna, the radio wave reflected by the first reflecting surface is transmitted through the second reflecting surface, and the aircraft Irradiated to the ground directly below. Therefore, in order to prevent the radar detection characteristics from deteriorating due to the influence of clutter existing in the ground direction, it is necessary to reduce the side lobes in the ground direction. There was a problem that it was not applied.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an antenna device that can reduce side lobes in the ground direction without causing a decrease in gain in the radio wave radiation direction. .

  An antenna device according to the present invention is mounted on a flying object flying in the air and has an array antenna composed of a plurality of element antennas forming an antenna opening surface, and a cylindrical wall surface disposed around the array antenna, A cylindrical wall surface is provided with a reflecting surface that reflects radio waves radiated from the array antenna, or a structure that acts as a transmission surface that transmits radio waves, and the control unit is configured to move from the array antenna among the wall surfaces of the structure. The wall surface in the line-of-sight range in the ground direction is set as a reflection surface, and the wall surface not in the line-of-sight range in the ground direction is set as a transmission surface.

  According to this invention, the cylindrical wall surface disposed around the array antenna has a cylindrical wall surface that acts as a reflective surface that reflects radio waves radiated from the array antenna or a transmissive surface that transmits radio waves. The control unit sets a wall surface of the structure having a line-of-sight range from the array antenna to the ground direction as a reflection surface, and sets a wall surface not in the line-of-sight range to the ground surface as a transmission surface. Since it comprised in this way, there exists an effect which can reduce the side lobe of a ground direction, without causing the fall of the gain of a radio wave radiation direction.

It is a block diagram which shows the antenna apparatus by Embodiment 1 of this invention. It is explanatory drawing which shows an antenna apparatus when the radiation | emission direction of an electromagnetic wave corresponds with the advancing direction of an aircraft. It is explanatory drawing which looked at the antenna apparatus which has set the lower half of the cylindrical wall surface 2a to the reflective surface from the front. It is explanatory drawing which shows an antenna apparatus when the radiation | emission direction of an electromagnetic wave corresponds with the advancing direction of an aircraft. It is explanatory drawing which looked at the antenna apparatus which has set the range smaller than the lower half of the cylindrical wall surface 2a from the front. It is explanatory drawing which shows the radiation characteristic of an array antenna. It is explanatory drawing which shows the example of arrangement | positioning of the metal pattern 3 and the switch element 4. FIG. It is explanatory drawing which shows the example of arrangement | positioning of the metal pattern 3 and the switch element 4. FIG. It is a block diagram which shows the 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 relationship between the attitude | position of an aircraft, and a setting reflective surface.

  Hereinafter, in order to describe the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.

Embodiment 1 FIG.
1 is a block diagram showing an antenna apparatus according to Embodiment 1 of the present invention.
In FIG. 1, the element antennas 1 are arranged in an array to constitute an array antenna.
In the example of FIG. 1, a plurality of element antennas 1 are two-dimensionally arranged in a circle to form an antenna opening surface, and an array antenna composed of a plurality of element antennas 1 is mounted on a flying object such as an aircraft flying in the air. Has been.

The structure 2 has a cylindrical wall surface 2a disposed around the plurality of element antennas 1 constituting the array antenna. The cylindrical wall surface 2a is formed of, for example, a dielectric substrate. Yes.
The cylindrical wall surface 2a of the structure 2 functions as a reflection surface that reflects radio waves radiated from the plurality of element antennas 1 or a transmission surface that transmits radio waves.
Metal patterns 3 are periodically arranged on the cylindrical wall surface 2 a, and switch elements 4 are connected between the plurality of metal patterns 3.
As the switch element 4, for example, an active element such as a Pin diode can be used.
In FIG. 1, the metal pattern 3 and the switch element 4 seem to be formed on a part of the cylindrical wall surface 2 a, but actually, the metal pattern 3 extends over the entire circumference of the cylindrical wall surface 2 a. The switch element 4 is formed.

The control unit 5 controls the open / close state of the plurality of switch elements 4 formed over the entire circumference of the cylindrical wall surface 2a, so that the line-of-sight range from the array antenna to the ground direction of the cylindrical wall surface 2a is controlled. The wall surface 2a is set as a reflection surface, and the wall surface 2a that is not in the line-of-sight range in the ground direction is set as a transmission surface.
For example, when the switch element 4 is in the ON state (closed state), the plurality of metal patterns 3 are electrically connected in the vertical direction in the figure, and thus extend in the direction along the circumference of the structure 2. A linear conductor is formed. The linear conductor operates as a reflecting surface when the conductor length is longer than half the wavelength of the radio wave radiated from the array antenna. Therefore, when the switch element 4 is turned on, the wall surface 2a operates as the reflecting surface.
On the other hand, when the switch element 4 is in the OFF state (open state), the metal pattern 3 becomes an isolated metal. When the length of the isolated metal is sufficiently shorter than the wavelength of the radio wave radiated from the array antenna, for example, when it is shorter than about ¼ wavelength, the radio wave is transmitted because the metal does not operate as a reflecting surface. That is, when the switch element 4 is turned off, the wall surface 2a operates as a transmission surface.

Next, the operation will be described.
In the first embodiment, a flying object such as an aircraft equipped with an array antenna composed of a plurality of element antennas 1 flies in the horizontal direction, and the radiation direction of the radio wave substantially coincides with the traveling direction of the aircraft. Suppose.
FIG. 2 is an explanatory diagram showing the antenna device when the radiation direction of the radio wave coincides with the traveling direction of the aircraft.
In the example of FIG. 2, when the ground direction is vertically downward and the antenna device is used as a radar antenna to observe a long distance in the horizontal direction, the radar detection characteristics deteriorate due to the influence of clutter existing in the ground direction. To do. In order to prevent the radar detection characteristics from deteriorating due to the influence of the clutter, it is necessary to reduce the side lobes of the array antenna in the ground direction.

Therefore, in the first embodiment, the control unit 5 controls the open / close state of the plurality of switch elements 4 formed over the entire circumference of the cylindrical wall surface 2a, so that the cylindrical wall surface 2a The wall surface 2a in the line-of-sight range from the array antenna to the ground direction is set as a reflection surface, and the wall surface 2a that is not in the line-of-sight range in the ground direction is set as a transmission surface.
The line-of-sight range from the array antenna to the ground surface varies depending on the width of the cylindrical wall surface 2a, that is, the dimension of the wall surface 2a in the radiation direction of the radio wave radiated from the array antenna. In the case where the length of the radio wave radiated from the array antenna has a length corresponding to 5 wavelengths, the lower half of the cylindrical wall surface 2a becomes the line-of-sight range in the ground direction.

In this case, the control unit 5 controls the switch element 4 existing in the lower half of the cylindrical wall surface 2a to be in an ON state so that the metal pattern 3 existing in the lower half of the cylindrical wall surface 2a is connected. Thus, as shown in FIG. 2, the lower half of the cylindrical wall surface 2a is set as a reflection surface.
On the other hand, the switch element 4 existing in the upper half of the cylindrical wall 2a is controlled to be in an OFF state so that the metal pattern 3 existing in the upper half of the cylindrical wall 2a is isolated. As shown in FIG. 2, the upper half of the cylindrical wall surface 2a is set as the transmission surface.
FIG. 3 is an explanatory diagram viewed from the front of the antenna device in which the lower half of the cylindrical wall surface 2a is set as a reflection surface.

Here, an example is shown in which the lower half of the cylindrical wall surface 2a is a line-of-sight range in the ground direction. However, when the width of the cylindrical wall surface 2a is longer than the length of five wavelengths of radio waves, the cylindrical wall surface The range less than the lower half of 2a is the line-of-sight range toward the ground. In this case, as shown in FIG. 4, the control unit 5 sets a range smaller than the lower half of the cylindrical wall surface 2a as the reflecting surface.
FIG. 5 is an explanatory diagram viewed from the front of an antenna device in which a range smaller than the lower half of the cylindrical wall surface 2a is set as a reflecting surface.

The line-of-sight range from the array antenna to the ground is strictly determined by factors such as the wavelength of the radio wave radiated from the array antenna and the width of the cylindrical wall surface 2a, as well as the diameter of the structure 2. Is.
However, since these elements are known elements at the time of designing the antenna device, the line-of-sight range from the array antenna to the ground in the antenna device is also known.
Therefore, in the first embodiment, it is assumed that the control unit 5 knows in advance which range of the wall surface 2a of the cylindrical wall surface 2a is the wall surface 2a of the line-of-sight range.

FIG. 6 is an explanatory diagram showing the radiation characteristics of the array antenna.
In FIG. 6, the broken line indicates the radiation characteristic when the entire circumference of the cylindrical wall surface 2a is a transmission surface (when no reflection surface is set), and the solid line indicates a part of the cylindrical wall surface 2a. Shows the radiation characteristics when is a reflecting surface (when the reflecting surface is set as shown in FIGS. 2 and 3).
FIG. 6 shows the analysis result of the radiation characteristics of the vertical surface of the array antenna alone when the width of the cylindrical wall surface 2a is the length of five wavelengths of radio waves.

In the figure, the 0 degree direction is the radio wave radiation direction, and the -90 degree direction is the ground direction.
When the entire circumference of the cylindrical wall surface 2a is a transmission surface (when no reflection surface is set), it is confirmed that the side lobe in the ground direction is about −2 [dBi].
The gain in the radio wave radiation direction hardly changes depending on whether or not the reflecting surface is set, but the gain in the ground direction is reduced by 10 dB or more when the reflecting surface is set and when the reflecting surface is not set. The gain in the ground direction when the reflecting surface is set is about −15 [dBi].
Thus, it can be seen that setting the reflecting surface reduces the side lobes in the ground direction without causing a decrease in gain in the radio wave radiation direction.
When the entire circumference of the cylindrical wall surface 2a is set as a reflection surface, side lobes in the ground direction deteriorate due to reflection on the reflection surface in a range other than the reflection surface shown in FIGS. Moreover, since the range reflected by the structure 2 becomes large, the gain in the radio wave radiation direction is reduced.

  As apparent from the above, according to the first embodiment, the cylindrical wall surface 2a is disposed around the array antenna, and the cylindrical wall surface 2a reflects the radio waves radiated from the array antenna. A structure 2 that acts as a surface or a transmission surface that transmits radio waves, and the control unit 5 uses, as a reflection surface, a wall surface 2a that is visible from the array antenna to the ground surface among the wall surfaces 2a of the structure 2 Since it is configured to set the wall surface 2a that is not the line-of-sight range in the ground direction as the transmission surface, the side lobe in the ground direction can be reduced without causing a decrease in the gain in the radio wave radiation direction. .

In the first embodiment, the radio wave radiated from the array antenna is vertically polarized wave, and when the switch element 4 is turned on, an example in which a reflecting surface that reflects the vertically polarized wave is set is shown. When the radio wave radiated from the antenna is horizontally polarized, as shown in FIG. 7, the switch element 4 that connects between the metal patterns 3 arranged in the horizontal direction is arranged, and the control unit 5 A reflective surface that reflects horizontal polarization may be set by controlling to the ON state.
Further, when the radio wave radiated from the array antenna is composed of polarized waves in the vertical direction and the horizontal direction, as in the case of circularly polarized waves, for example, as shown in FIG. And the switch element 4 for connecting between the metal patterns 3 arranged in the horizontal direction, and the control unit 5 controls each switch element 4 to be in an ON state, so that the vertical direction You may make it set the reflective surface which reflects the horizontal polarized-wave.

  The first embodiment shows an example in which the width of the cylindrical wall surface 2a is a length corresponding to five wavelengths of radio waves, and the level of side lobe reduction in the ground direction varies depending on the width of the cylindrical wall surface 2a. However, if the width of the cylindrical wall surface 2a is generally larger than the length of three wavelengths of radio waves, the side lobe reduction effect can be obtained.

Embodiment 2. FIG.
In the first embodiment, the example in which the metal pattern 3 and the switch element 4 are arranged on the cylindrical wall surface 2a has been described. However, the cylindrical wall surface 2a is divided into a plurality of regions, and plasma is applied to each region. A discharge tube may be arranged.

9 is a block diagram showing an antenna apparatus according to Embodiment 2 of the present invention. In FIG. 9, the same reference numerals as those in FIG.
In the antenna device of FIG. 9, the cylindrical wall surface 2a is divided into a plurality of regions.
The plasma discharge tube 11 is arranged in a plurality of regions.
The plasma discharge tube 11 has a plate-like hollow structure, and an ionizing gas is sealed inside.
Here, it is assumed that the plasma discharge tubes 11 are arranged in each region of the cylindrical wall surface 2a formed of a dielectric substrate or the like, but a plurality of plasma discharge tubes 11 are arranged in a circle. Thus, the plasma discharge tube 11 may carry the cylindrical wall surface 2a.
The plasma power source 12 is a power source for exciting the gas sealed in the plasma discharge tube 11 to a plasma state.
In the example of FIG. 9, the plasma discharge tube 11 and the plasma power source 12 are connected on a one-to-one basis, but one plasma power source 12 excites the gas sealed in the plurality of plasma discharge tubes 11 into a plasma state. It may be a thing.

The control unit 13 controls the plasma power source 12 to set the wall surface 2a in the line-of-sight range from the array antenna to the ground direction among the wall surfaces 2a of the structure 2 as a reflection surface, and a wall surface that is not in the line-of-sight range in the ground direction. 2a is set as the transmission surface.
That is, when the gas sealed in the plasma discharge tube 11 is in a plasma state, it acts to reflect radio waves, and the gas sealed in the plasma discharge tube 11 is in a normal gas state (non-plasma state). Since it acts to transmit radio waves, the control unit 13 turns on the plasma power source 12 corresponding to the plasma discharge tube 11 disposed on the wall surface 2a of the line-of-sight range in the ground direction (the voltage is changed). The plasma power source 12 corresponding to the plasma discharge tube 11 disposed on the wall surface 2a that is not in the visible range toward the ground is controlled to be in an OFF state (a state where no voltage is applied). To do.
In FIG. 9, for simplification of the drawing, the control unit 13 is connected to only a part of the plasma power sources 12, but is connected to all the plasma power sources 12.

Next, the operation will be described.
The control unit 13 controls the plasma power source 12 corresponding to the plasma discharge tube 11 disposed on the wall surface 2a in the line-of-sight range in the ground direction, and is disposed in the wall surface 2a that is not in the line-of-sight range in the ground direction. The plasma power source 12 corresponding to the plasma discharge tube 11 is controlled to be turned off.
As a result, the plasma discharge tube 11 connected to the plasma power source 12 in the ON state, that is, the plasma discharge tube 11 arranged on the wall surface 2a in the line-of-sight range toward the ground, is excited by the gas inside. Therefore, it acts as a reflecting surface that reflects radio waves.
In addition, the plasma discharge tube 11 connected to the plasma power source 12 in the OFF state, that is, the plasma discharge tube 11 disposed on the wall surface 2a that is not in the range of the line of sight toward the ground, has an internal gas in a normal gas state ( Since it is in a non-plasma state, it acts as a transmission surface that transmits radio waves.

Therefore, in the case of the second embodiment, similarly to the first embodiment, the side lobe in the ground direction can be reduced without causing a decrease in the gain in the radio wave radiation direction.
In the second embodiment, the plasma discharge tube 11 has a plate-like hollow structure. However, the present invention is not limited to this, and for example, a plurality of thin tubes in which ionizing gas is sealed. The tube may be periodically arranged, or a thin tube in which an ionizing gas is sealed may be stretched in a planar shape.

Embodiment 3 FIG.
In the said Embodiment 1, 2, although the control parts 5 and 13 showed what knows beforehand the wall surface 2a of the range which is the line-of-sight range wall surface 2a among the cylindrical wall surfaces 2a, When the attitude of a flying object such as an aircraft is inclined, the wall surface 2a of the line-of-sight range toward the ground changes.
Therefore, in the third embodiment, a description will be given of an apparatus that includes an inclination detection unit that detects the inclination of the attitude of the flying object, and that identifies the wall surface 2a of the line-of-sight range in the ground direction from the inclination of the attitude of the flying object.

10 is a block diagram showing an antenna apparatus according to Embodiment 3 of the present invention. In FIG. 10, the same reference numerals as those in FIG.
The tilt detection unit 21 is a sensor that detects the tilt of the posture of a flying object such as an aircraft.
The control unit 22 has a line-of-sight wall 2a in a state in which the attitude of the aircraft is not tilted in advance. The wall surface 2a of the range is specified.
After specifying the wall surface 2a of the line-of-sight range in the ground direction, the control unit 22 controls the switch element 4 in the same manner as the control unit 5 in FIG. The wall surface 2a in the line-of-sight range from the antenna to the ground is set as a reflection surface, and the wall surface 2a that is not in the line-of-sight range in the ground direction is set as a transmission surface.

10 shows an example in which the tilt detection unit 21 and the control unit 22 are applied to the antenna device of FIG. 1, but the tilt detection unit 21 and the control unit 22 are applied to the antenna device of FIG. It may be.
In this case, the control unit 22 controls the plasma power source 12 in the same manner as the control unit 13 of FIG. 9, so that the wall surface 2 a in the line-of-sight range from the array antenna to the ground direction among the wall surfaces 2 a of the structure 2. The reflecting surface is set, and the wall surface 2a that is not in the line-of-sight range toward the ground is set as the transmitting surface.

Next, the operation will be described.
The inclination detector 21 detects the inclination of the attitude of the aircraft.
FIG. 11 is an explanatory diagram showing the relationship between the attitude of the aircraft and the set reflecting surface.
FIG. 11A shows a case where the attitude of the aircraft is not tilted, and FIG. 11B shows a case where the attitude of the aircraft is tilted.
However, FIG. 11 shows an example in which the range of the reflecting surface is generally in the range where the central angle is 90 degrees.

If the detection result of the inclination detection unit 21 indicates that the attitude of the aircraft is not inclined, the control unit 22 sets the wall surface 2a of the line-of-sight range that is set in advance among the wall surfaces 2a of the structure 2, It is recognized that the wall surface 2a is still in the sight range.
If the detection result of the inclination detection unit 21 indicates that the attitude of the aircraft is inclined, the control unit 22 identifies the wall surface 2a in the line-of-sight range from the inclination angle.
For example, as shown in FIG. 11 (b), if the attitude of the aircraft is inclined 30 degrees in the counterclockwise direction when viewed from the front, it is set in advance and 30 degrees clockwise from the wall surface 2a of the line-of-sight range. Is recognized as a wall surface 2a in the current line-of-sight range.

  After specifying the wall surface 2a of the line-of-sight range in the ground direction, the control unit 22 controls the switch element 4 in the same manner as the control unit 5 in FIG. The wall surface 2a in the line-of-sight range from the antenna to the ground is set as a reflection surface, and the wall surface 2a that is not in the line-of-sight range in the ground direction is set as a transmission surface.

  As is apparent from the above, according to the third embodiment, the inclination detection unit 21 that detects the inclination of the aircraft attitude is provided, and the control unit 22 detects the inclination of the aircraft attitude detected by the inclination detection unit 21. Since the wall surface 2a of the line-of-sight range from the array antenna to the ground direction is specified, even if the attitude of the aircraft is tilted, the side lobe in the ground direction is reduced without causing a decrease in the gain in the radio wave radiation direction. There is an effect that can be reduced.

  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. .

  DESCRIPTION OF SYMBOLS 1 Element antenna, 2 structure, 2a wall surface, 3 metal pattern, 4 switch element, 5 control part, 11 plasma discharge tube, 12 plasma power supply, 13 control part, 21 inclination detection part, 22 control part.

Claims (4)

An array antenna composed of a plurality of element antennas mounted on a flying object flying in the air and forming an antenna opening surface;
A structure having a cylindrical wall surface disposed around the array antenna, wherein the cylindrical wall surface acts as a reflecting surface for reflecting the radio waves radiated from the array antenna or a transmitting surface for transmitting the radio waves Things,
An antenna comprising: a control unit configured to set a wall surface in a line-of-sight range from the array antenna to the ground direction as a reflective surface and a wall surface not in the line-of-sight range in the ground direction as a transmission surface among the wall surfaces of the structure apparatus. An inclination detector for detecting the inclination of the attitude of the flying object;
The antenna device according to claim 1, wherein the control unit specifies a wall surface in a line-of-sight range from the array antenna toward the ground based on the inclination of the attitude of the flying object detected by the inclination detection unit. The structure is
A plurality of metal patterns arranged in an array on the cylindrical wall;
A plurality of switch elements for connecting between the plurality of metal patterns,
The control unit controls the open / close state of the plurality of switch elements to set a wall surface in a line-of-sight range from the array antenna to the ground direction as a reflecting surface among the wall surfaces of the structure, 3. The antenna device according to claim 1, wherein a wall surface that is not in a line-of-sight range is set as a transmission surface. The cylindrical wall surface of the structure is divided into a plurality of regions,
In the plurality of regions, a plasma discharge tube in which an ionizing gas is sealed is disposed,
A plasma power source is connected to the plasma discharge tube to excite the gas into a plasma state.
The control unit controls the plasma power supply to set a wall surface in a line-of-sight range from the array antenna to the ground direction among the wall surfaces of the structure as a reflection surface, and is not in the line-of-sight range in the ground direction. 3. The antenna device according to claim 1, wherein the wall surface is set as a transmission surface.

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