JPH0998016A - Microstrip antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a microstrip antenna which excels in heat resistance with reduced inside gass and wide-band characteristic by using an expanded polyimide material to a dielectric layer placed between a feed element and a non-feed element. SOLUTION: A microstrip antenna 7 serving as a feed element consists of a ground conductor 1, a 1st dielectric substrate 2 and a 1st radiation conductor 5. A non-feed element consists of a 2nd dielectric substrate 4 and a 2nd radiation conductor 6. Then an expanded polyimide material is used to a dielectric layer 10 which is placed between the feed element and the non-feed element. The expanded polyimide material excels in the heat resistance and has the reduced gass inside and therefore can be used under vacuum, i.e., in such a place as the outer space, etc., where the temperature change is large with the severe environmental conditions. The conductors 5 and 6 are available in the square, triangular and elliptical shapes, etc., and the feed systems include a system using a microstrip line, a system using a triplet line, an electromagnetic coupling system, a near-by feed system, etc.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microstrip antenna having a wide band characteristic with good environment resistance.

[0002]

2. Description of the Related Art FIG. 8 shows a conventional example such as Hori, Nakajima,
"Broadband coplanar feed circularly polarized microstrip antenna", IEICE Transactions (B), Vol. J68
-B, No. It is a block diagram which shows the cross section of the microstrip antenna which has the conventional parasitic element shown in pages 4,515-522. In the figure, 1 is a ground conductor, 2
Is a first dielectric substrate, 3 is a dielectric layer, 4 is a second dielectric substrate, 5 is a first radiation conductor, 6 is a second radiation conductor, and a ground conductor, a first dielectric substrate The first radiation conductor constitutes the microstrip antenna 7 as a feeding element. Further, the parasitic element is composed of the second dielectric substrate and the second radiation conductor. Reference numeral 8 is a power supply pin for supplying power to the microstrip antenna, and 9 is a power supply connector.

Next, the operation will be described. Since the microstrip antenna operates as a resonator, it generally has a narrow band. In order to widen the band, it is necessary to use a dielectric substrate having a small dielectric constant or to increase the substrate thickness. However, in order to secure a bandwidth of about 10%, there is a problem that the substrate becomes thick and thus the weight increases or the cost becomes high. As a proposal for improving these problems, a configuration in which a parasitic element is mounted on the upper part of the feeding element has been reported. By using an air layer as the dielectric layer between the feeding element and the parasitic element, the dielectric constant is equivalently reduced and the substrate is thickened. Therefore, a wide band characteristic can be easily realized with a simple configuration.

[0004]

In order to realize a wide band characteristic by using the parasitic element, the dielectric layer between the feeding element and the feeding element generally has an air layer or a dielectric constant close to that of the air layer. Foam material is used. Examples of the foam material include polystyrene foam and urethane foam. These foam materials are lightweight and low cost, and are widely used in a low frequency band (for example, UHF band, L band, S band, etc.).
However, in the high frequency band such as the Ka band or the millimeter wave band, the wavelength becomes about several millimeters and dimensional accuracy is required. When a foam material is used, there is a large variation in thickness, and due to its flexibility, dimensional accuracy cannot be ensured. Further, even in the case of an air layer, a spacer is required to support the parasitic element, and the dimensional accuracy cannot be ensured due to variations in the way it is supported, and there is the problem that it cannot be used in the Ka band or millimeter wave band. Furthermore, when used at room temperature on the ground, environmental conditions are good. However, when the temperature change is extremely large, such as in outer space, there is a problem that shrinkage due to the temperature change and particularly the foam material has weak heat resistance and earthquake resistance.

Further, when a plurality of microstrip antennas are arranged to form an array antenna and the structure has periodicity, a beam is formed in a direction different from a desired direction in which the periodicity is in phase, and side lobes are formed. There is a problem that will rise. Further, when used in outer space, there is a problem in that the parasitic element is charged by the radiation in the space, and noise is generated due to its discharge, which hinders communication. Further, as a dielectric substrate that constitutes the feeding element or the parasitic element, a fluorine resin substrate or a substrate obtained by folding glass fibers is often used. It is a low-loss substrate and has excellent properties when used at room temperature.
However, there is a problem that the coefficient of thermal expansion is large in a space having a large temperature change such as outer space, and that the contraction and the change of the dielectric constant due to the temperature change have a great influence on the deterioration of the electrical characteristics and the mechanical strength. Therefore, it is an object of the present invention to obtain a microstrip antenna having wide environment resistance and good environmental resistance that can provide stable characteristics in a space where temperature changes greatly, such as outer space.

[0006]

In order to solve the above problems, the microstrip antenna according to the first embodiment of the present invention uses a foamed polyimide material as a dielectric layer between a feeding element and a parasitic element. It is a thing.

The microstrip antenna according to the second embodiment of the present invention is one in which a plurality of holes are provided in the dielectric plate between the feeding element and the parasitic element.

The microstrip antenna according to the third embodiment of the present invention is substantially the same as or larger than the parasitic element on the dielectric plate between the feeding element and the parasitic element, substantially below the parasitic element. It has holes.

Further, a microstrip antenna according to a fourth embodiment of the present invention is one in which a plurality of holes provided in a dielectric plate between a feeding element and a parasitic element are randomly arranged.

Further, the microstrip antenna according to the fifth embodiment of the present invention is one in which the central portions of the feeding element and the parasitic element are connected to the ground conductor by a conductor and grounded.

The microstrip antenna according to the sixth embodiment of the present invention is provided with a degenerate separation element for exciting a circularly polarized wave in each of the feeding element or the parasitic element or both the feeding element and the parasitic element. is there.

Further, the microstrip antenna according to the seventh embodiment of the present invention is one in which a plurality of microstrip antennas provided with degenerate separation elements and excited by circular polarization are arranged as a sequential array.

Further, the microstrip antenna according to the eighth embodiment of the present invention uses an aramid fiber reinforced plastic having a small coefficient of thermal expansion as a feeding element or a parasitic element or a dielectric plate between the feeding element and the parasitic element. It was what I had.

Further, the microstrip antenna according to the ninth embodiment of the present invention uses quartz fiber reinforced plastic having a small dielectric loss as a dielectric plate between the feeding element or the parasitic element or the feeding element and the parasitic element. It was what I had.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1. FIG. 1 is a schematic configuration diagram showing Embodiment 1 of the present invention. In the figure, 1 is a ground conductor, 2 is a first dielectric substrate, 4 is a second dielectric substrate, 5 is a first radiation conductor, 6 is a second radiation conductor, and the ground conductor, the first The dielectric substrate and the first radiation conductor constitute the microstrip antenna 7 which is a feeding element. Second dielectric substrate, second
The parasitic element is composed of the radiation conductor of. Reference numeral 10 is a dielectric layer inserted between the feeding element and the parasitic element, and uses a foamed polyimide material.

Next, the operation principle will be described. Ordinary foam materials have low heat resistance and the environmental conditions in which they can be used are limited. On the other hand, this foamed polyimide material has excellent heat resistance and little degassing, so that it can be used in a vacuum. That is, it can be used in a place where temperature changes are large and environmental conditions are severe, such as outer space. Here, an example of a circular microstrip antenna is shown as the radiation conductor, but the present invention is also effective for other shapes such as a square, a triangle, and an ellipse. Also, as an example of the power feeding method, the power feeding pin is used to feed power from the back surface.However, a method of feeding power from the coplanar plane with the power feeding element using a microstrip line, or feeding using a triplate line, or providing a slot in the ground conductor and inserting a slot The present invention is also effective in other power feeding methods such as an electromagnetic coupling method in which power is supplied electromagnetically by electromagnetic waves, or a proximity power feeding method in which a microstrip line and a radiation conductor are brought close to each other to feed power.

Embodiment 2. 2 is a schematic configuration diagram showing a second embodiment of the present invention. In the figure, 1 is a ground conductor, 2 is a first dielectric substrate, 4 is a second dielectric substrate, 5
Is a first radiation conductor, 6 is a second radiation conductor, and the ground conductor, the first dielectric substrate, and the first radiation conductor constitute a microstrip antenna 7 as a feeding element. A parasitic element is composed of the second dielectric substrate and the second radiation conductor. Reference numeral 11 is a dielectric plate having a hole inserted between the feeding element and the parasitic element.

Next, the operation principle will be described. In order to realize wide band characteristics, a foam material having a low dielectric constant close to that of an air layer is preferable as a material between the parasitic element and the feeder element. Foamed polyimide has a low dielectric constant, excellent heat resistance, and little degassing, so it can be used in vacuum, but when dimensional accuracy is required, especially in the millimeter wave band, the desired dimensional accuracy is required. Hard to get. On the other hand, in order to obtain the desired dimensional accuracy, it is necessary to use a high-dielectric-constant substrate with high strength.
With this, wide band characteristics cannot be obtained. Therefore, by making a hole in the high-dielectric-constant substrate, the dielectric constant of the substrate is equivalently reduced, and broadband characteristics can be easily obtained. further,
Since the accuracy of the substrate thickness can be secured, the variation is small. An aramid-based fiber-reinforced plastic having a small coefficient of thermal expansion is used as a dielectric substrate between the feeding element or the parasitic element or the feeding element and the parasitic element. Here, an example of a circular microstrip antenna is shown as the radiation conductor, but the present invention is also effective for other shapes such as a square, a triangle, and an ellipse. Also, as an example of the power feeding method, the power feeding pin is used to feed power from the back surface.However, a method of feeding power from the coplanar plane with the power feeding element using a microstrip line, or feeding using a triplate line, or providing a slot in the ground conductor and inserting a slot The present invention is also effective in other power feeding methods such as an electromagnetic coupling method in which power is supplied electromagnetically by electromagnetic waves, or a proximity power feeding method in which a microstrip line and a radiation conductor are brought close to each other to feed power. Further, although an example in which power is supplied at one location is shown here, it goes without saying that the present invention is also effective when power is supplied at two locations and circularly polarized waves are excited or orthogonal polarized waves are excited. .

Embodiment 3 FIG. 3 is a schematic configuration diagram showing a third embodiment of the present invention. In the figure, reference numeral 11 denotes a dielectric plate having a hole inserted between the feeding element and the parasitic element. An array antenna is constructed by arranging a plurality of microstrip antennas.

Next, the principle of operation will be described. The dielectric plate between the feeding element and the parasitic element is provided with a hole having a size substantially equal to or larger than that of the parasitic element. As a result, air can be provided between the feeding element and the parasitic element, so that the dielectric loss can be reduced and the band can be widened. Further, when the array antenna is configured, the equivalent dielectric constants of the respective elements are the same and variations are reduced. Although a circular shape is shown here as the shape of the hole, the present invention is also effective for other shapes such as a square, a triangle, and an ellipse.

Embodiment 4 FIG. 4 is a schematic configuration diagram showing a fourth embodiment of the present invention. In the figure, reference numeral 11 denotes a dielectric substrate having a hole inserted between the feeding element and the parasitic element. Arrange multiple microstrip antennas,
Configure an array antenna.

Next, the operation principle will be described. When an array antenna is constructed, a beam can be formed by matching the phases of the elements in a desired direction. The phase of each element is made in-phase, that is, its periodicity is utilized. Therefore, if there is periodicity, some beam is formed in the direction in which the periods are in phase. When holes are formed in the dielectric plate, if the holes are formed periodically, a beam is formed in the direction in which the surface wave modes propagating in the substrate are in phase, and the side lobes rise. The rise of the side lobe causes the emission of unnecessary radio waves in the case of transmission and the deterioration of the S / N ratio due to the increase of noise in the case of reception, and further reduces the antenna gain accordingly. Therefore, by arranging the holes irregularly, it is possible to eliminate the periodicity and suppress the rise of the side lobes. The size of the hole may be arbitrary, and a circular shape is shown here as an example, but the present invention is also effective for other shapes such as a square, a triangle, and an ellipse.

Embodiment 5 5 is a sectional view of a schematic configuration showing a fifth embodiment of the present invention. In the figure, 13
Is a pin that grounds the parasitic element to the ground conductor.

Next, the operation principle will be described. The parasitic element is provided in a non-contact manner on the upper side of the feeding element, and is fed electromagnetically from the feeding element. When this antenna is used in outer space, it will be charged by the influence of radiation in outer space. When this is discharged, noise is generated, which hinders communication. Therefore, grounding becomes possible by connecting the central part of the parasitic element to the ground conductor with a metal rod. Since the electric field at the center of the microstrip antenna is zero, the electromagnetic field is not disturbed even when connected by a metal rod, and the radiation pattern and input impedance do not change.

Embodiment 6 FIG. 6 is a schematic configuration diagram showing a sixth embodiment of the present invention. In the figure, 14, 15
Is a degenerate separation element for exciting the circularly polarized wave provided in the feeding element or the parasitic element.

Next, the operating principle will be described. As a method of exciting a circularly polarized wave, a feeding circuit having a two-point feeding method for feeding a phase difference of 90 degrees at two orthogonal positions becomes complicated.
In particular, when a branch line type hybrid circuit or the like is used for excitation in a high frequency band such as a millimeter wave band, a multilayer structure is formed, which makes manufacturing difficult. Therefore, circular polarization can be excited with a simple structure by feeding power at one location and mounting a degenerate separation element for solving the degeneracy on the radiating element or the parasitic element or both. Although the circular shape of the radiation conductor is shown here, other shapes such as a square, a triangle, and an ellipse may be used. Also, an example has been shown in which a recess is provided as the degenerate separation element on the outer circumference of the radiation conductor, but it may be a projection and does not depend on its shape. The present invention is effective even if a slot is provided at an angle of 45 degrees inside the radiation conductor.

Embodiment 7 7 is a schematic configuration diagram showing a seventh embodiment of the present invention. Circularly polarized waves can be excited with a simple structure by feeding power at one location and mounting degenerate separation elements for solving degeneration on the radiating element or the parasitic element or both, but the frequency characteristics of its axial ratio are narrow. It is a band. A wider band characteristic can be obtained by adopting a method of feeding power with a 90 degree phase difference at two orthogonal positions, but the power feeding circuit becomes complicated. Therefore, each element is rotated 180 / n (n = 1, 2, 3, ...) Degrees in an array antenna having a plurality of array antennas, and the phase is also 180 / n (n = 1, 2, 3, ...)
Excite with varying degrees (ie sequential array).
Even if one element is an elliptically polarized wave, a perfect circularly polarized wave with a good axial ratio can be excited over a wide band. Although the circular shape of the radiation conductor is shown here, other shapes such as a square, a triangle, and an ellipse may be used. Also, an example has been shown in which a recess is provided as the degenerate separation element on the outer circumference of the radiation conductor, but it may be a projection and does not depend on its shape. Although an example of four elements is shown here,
The present invention is effective as long as it is more than the element.

Embodiment 8 As the dielectric substrate, a low loss fluorine resin substrate or a substrate formed by folding a glass fiber material into this is often used, and it is a low loss and excellent substrate at room temperature. However, in a space with large temperature changes such as outer space, the coefficient of thermal expansion is large, and the electrical properties deteriorate due to contraction and changes in the dielectric constant due to temperature changes, and the effect on mechanical strength is large. A configuration to do so is required. Therefore, the aramid fiber-reinforced plastic has a small coefficient of thermal expansion and can be used in a vacuum, and thus has excellent environmental resistance. Therefore, by using this material, it is possible to use it in a space with a severe environment such as outer space with a simple structure.

Embodiment 9 The dielectric substrate generally has a large loss as the frequency increases, and the loss becomes extremely large in the Ka band and the millimeter wave band. Since this loss is converted into heat, heat dissipation becomes a problem in outer space. Therefore, in the quartz-based fiber-reinforced plastic, the tan δ of the dielectric becomes small, so that the loss can be made small.

[0030]

According to the first embodiment of the present invention, a foamed polyimide material is used as the dielectric layer between the feeding element and the parasitic element, so that it has excellent heat resistance and little degassing, so that it does not depend on environmental conditions. Since it can be used, and has a low dielectric constant, it has an effect of obtaining a wide band characteristic.

According to the second embodiment of the present invention,
By providing a plurality of holes in the dielectric plate between the feeding element and the parasitic element, the dielectric constant can be reduced equivalently, so that broadband characteristics can be obtained, dimensional accuracy can be improved, and variations can be reduced.

According to the third embodiment of the present invention,
Dielectric loss can be reduced by forming a hole in the dielectric plate between the feeding element and the parasitic element that is approximately the same size as or larger than the size of the parasitic element. The effective dielectric constants are the same, which has the effect of reducing variations.

According to the fourth embodiment of the present invention,
By randomly arranging a plurality of holes provided in the dielectric plate between the feeding element and the parasitic element, it is possible to reduce the rise of the side lobe due to the excitation of the surface wave.

According to the fifth embodiment of the present invention,
By connecting the central portions of the feeding element and the parasitic element with the ground conductor and the conductor, charging can be suppressed and noise can be reduced.

According to the sixth embodiment of the present invention,
By providing degenerate separation elements for exciting circular polarized waves in the feed element, the parasitic element, or both the feed element and the parasitic element, circular polarization can be excited with a simple configuration.

According to the seventh embodiment of the present invention,
By arranging a plurality of microstrip antennas as a sequential array, it is possible to obtain circular polarization characteristics over a wide band with a simple configuration.

According to the eighth embodiment of the present invention,
By using an aramid fiber-reinforced plastic having a small coefficient of thermal expansion as a dielectric substrate between the feeding element or the parasitic element or the feeding element and the parasitic element, an antenna having excellent environment resistance can be obtained.

According to the ninth embodiment of the present invention,
An antenna with a small dielectric loss can be obtained by using a quartz fiber-reinforced plastic having a small tan δ as the dielectric substrate between the feeding element or the parasitic element or the feeding element and the parasitic element.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a first embodiment of a microstrip antenna according to the present invention.

FIG. 2 is a schematic configuration diagram showing a second embodiment of a microstrip antenna according to the present invention.

FIG. 3 is a schematic configuration diagram showing a third embodiment of a microstrip antenna according to the present invention.

FIG. 4 is a schematic configuration diagram showing a fourth embodiment of a microstrip antenna according to the present invention.

FIG. 5 is a schematic configuration diagram showing a fifth embodiment of a microstrip antenna according to the present invention.

FIG. 6 is a schematic configuration diagram showing a sixth embodiment of a microstrip antenna according to the present invention.

FIG. 7 is a schematic configuration diagram showing a seventh embodiment of a microstrip antenna according to the present invention.

FIG. 8 is a schematic configuration diagram showing a conventional invention.

[Explanation of symbols]

1 ground conductor, 2 1st dielectric substrate, 3 dielectric layer (air layer), 4 2nd dielectric substrate, 5 1st radiation conductor,
6 second radiating conductor, 7 microstrip antenna,
8 feeding pin, 9 feeding connector, 10 foamed polyimide material, 11 dielectric plate, 12 hole provided in dielectric plate, 1
3 ground pins, 14 degenerate isolation elements provided on the first radiation conductor, 15 degenerate isolation elements provided on the first radiation conductor.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Norimitsu Negishi 2-3-3 Marunouchi, Chiyoda-ku, Tokyo Sanryo Electric Co., Ltd.

Claims (10)

[Claims] 1. A ground conductor, a first dielectric substrate provided on the ground conductor, and a first radiation conductor provided on a surface of the first dielectric substrate opposite to the ground conductor. Feeding element,
The dielectric layer provided on the first feeding element, the second dielectric substrate provided on the dielectric layer, and the second radiation conductor provided on the second dielectric substrate are sequentially laminated, and A microstrip antenna comprising a power feeding circuit for feeding a power feeding element, wherein a foamed polyimide material is used for the dielectric layer. 2. A ground conductor, a first dielectric substrate provided on the ground conductor, and a first radiation conductor provided on a surface of the first dielectric substrate opposite to the ground conductor. Feeding element,
The dielectric plate provided on the first feeding element, the second dielectric substrate provided on the dielectric plate, and the second radiation conductor provided on the second dielectric substrate are sequentially laminated, and A microstrip antenna comprising a feeding circuit for feeding a feeding element, wherein the dielectric plate is provided with a plurality of holes. 3. A ground conductor, a first dielectric substrate provided on the ground conductor, and a first radiation conductor provided on a surface of the first dielectric substrate opposite to the ground conductor. Feeding element,
The dielectric plate provided on the first feeding element, the second dielectric substrate provided on the dielectric plate, and the second radiation conductor provided on the second dielectric substrate are sequentially laminated, and In a microstrip antenna configured with a feeding circuit for feeding a feeding element, a plurality of holes are provided in the dielectric plate, and a central portion of the plurality of holes and a central portion of the second radiating conductor are substantially aligned with each other. The size of the hole is substantially the same as or larger than that of the second radiation conductor. 4. A ground conductor, a first dielectric substrate provided on the ground conductor, and a first radiation conductor provided on a surface of the first dielectric substrate opposite to the ground conductor. Feeding element,
The dielectric plate provided on the first feeding element, the second dielectric substrate provided on the dielectric plate, and the second radiation conductor provided on the second dielectric substrate are sequentially laminated, and A microstrip antenna comprising a power feeding circuit for feeding a power feeding element, wherein the dielectric plate is provided with a plurality of holes, and the plurality of holes are arranged irregularly. 5. The ground conductor, the first radiation conductor, and the second radiation conductor are connected by a metal rod.
Microstrip antenna of any one of 4 to 4. 6. A degenerate separation element for exciting a circularly polarized wave is provided on either or both of the first radiation conductor and the second radiation conductor.
Any of the microstrip antennas. 7. The microstrip antenna according to claim 6, wherein the microstrip antenna is an array antenna in which a plurality of the microstrip antennas are arrayed, and the microstrip antennas are arrayed as a sequential array. 8. An aramid fiber reinforced plastic (FRP) material is used for the dielectric plate, the first and second dielectric substrates, or both. Microstrip antenna. 9. A quartz fiber reinforced plastic (FRP) material is used for the dielectric plate, the first and second dielectric substrates, or both of the dielectric plates. Microstrip antenna. 10. The microstrip antenna according to claim 1, wherein the dielectric plate and the first and second dielectric substrates are adhered by a polycyanate adhesive.