JP6980194B2 - Phased array antenna system - Google Patents

Description

The present invention relates to a phased array antenna system.

Wireless communication using the 60 GHz band, which can use a wide band of about 9 GHz in many countries, is actively used for uncompressed video transmission and multi-gigabit wireless LAN (Local Area Network) as a frequency band for unlicensed wireless communication. It has become. The baseband portion of the communication module in such a frequency band is a system-on-package, and the communication module in which the RF (Radio Frequency) circuit and the phased array antenna are system-on-package is the mainstream. In the future, it is expected that the same configuration will be applied not only to the 60 GHz band but also to the millimeter wave band wireless communication module.

Since the wavelength of the high frequency band is short, it is possible to create a narrow radio wave with an antenna having a smaller aperture than the microwave band. Narrowing the width (beam width) of such radio waves is called narrowing the beam. By narrowing the beam, it is possible to perform parallel transmission in which multiple communications are performed using the same frequency band, and it is possible to arrange terminals at high density and perform simultaneous communications.Therefore, the advantage of communication using millimeter waves is wideband. Is not only available, but even bigger.

In order to narrow the beam width further than the beam width of the millimeter-wave communication module and perform the above-mentioned parallel transmission and high-density communication, use an external condenser lens on the outside of the module. Is assumed. The off-the-shelf millimeter-wave communication module has a function (beam steering function) that electronically changes the direction of radio waves by a phased array antenna. However, when steering is performed with a configuration in which a condenser lens is externally attached to the antenna portion of such a module, there is no other way but to physically switch the position of the antenna. Therefore, narrowing the beam with a condenser lens is often not suitable for external attachment to a millimeter-wave communication module.

FIG. 15 is an explanatory diagram illustrating a conventional method of narrowing a beam by using a convex lens when the antenna directivity of the phased array antenna portion is set to the front. If there is a phased array antenna portion at the focal length of the convex lens, the radio wave transmitted through the convex lens becomes a plane wave and the beam width becomes narrow. As a result, the antenna gain increases. Beamwidth and gain depend on the size of the lens. The larger the lens, the larger the aperture surface size of the antenna, so that the radio wave becomes narrower and the antenna gain becomes larger. The dotted line in FIG. 15 indicates a ray of radio wave emitted from the phased array antenna portion.

Next, a method of beam steering the phased array antenna portion will be described. FIG. 16 shows a ray of radio waves that has been narrowed by a conventional method of narrowing the beam using a convex lens and further steered to the left. Focusing on the light rays transmitted through the convex lens, it can be seen that the direction of the radio waves remains in front only by shifting the central axis of the radio waves to the left.
As described above, when a condensing lens is applied to the phased array antenna, it can be seen that the beam steering function of the phased array antenna does not work.

The only way to perform beam steering while narrowing the beam using such a condensing lens is to change the position of the antenna element used in a plane on the focal length of the lens (Non-Patent Document 1). reference). In Non-Patent Document 1, as shown in FIG. 17, beam steering is realized by providing a plurality of antenna elements and switching the antenna to be used. However, it is desired to achieve both narrowing of the beam and beam steering without the need to switch the antenna.

Juha Ala-Laurinaho, et al., “2-D Beam-Steerable Integrated Lens Antenna System for 5G E-Band Access and Backhaul”, IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, VOL. 64, No. 7, JULY 2016.

In view of the above circumstances, it is an object of the present invention to provide an antenna system that achieves both narrowing and beam steering without switching an antenna that emits radio waves according to the radiation direction.

In one aspect of the present invention, a plurality of antenna elements that emit radio waves are provided in the same plane, and the distance from the same plane is parallel to the same plane, and the distance from the same plane is compared with the wavelength in the free space of the radio wave. A planar phased array antenna having a ground conductor plate that reflects the radio waves in a plane located at a position short enough to be ignored, and a flat plate-shaped dielectric parallel to the same plane in the broad side direction of the antenna element. The dielectric plate is provided with a dielectric plate located in the above, and the thickness of the dielectric plate is substantially the same as 1/4 of the antenna in the substance of the dielectric of the radio wave, and the thickness of the dielectric plate is substantially the same. This is a phased array antenna system in which the distance between the surface facing the antenna element and the surface provided with the antenna element is substantially the same as ½ of the wavelength in the free space of the radio wave.

One aspect of the present invention is the phased array antenna system described above, which comprises a plurality of the dielectric plates.

One aspect of the present invention is the phased array antenna system described above, wherein the planar phased array antenna is in a space sandwiched between the same plane and a plane provided with the ground conductor plate, and further in the same plane. H is provided with a parallel flat plate-shaped dielectric layer, and H is defined as a margin H, where the distance between the center point of each antenna element and the peripheral portion of the dielectric layer closest to each antenna element is a margin H. It is substantially the same as 3/4 of the wavelength in the free space of the radio wave.

One aspect of the invention is the phased array antenna system described above, comprising a negative meniscus lens located on the opposite side of the planar phased array antenna with the dielectric plate interposed therebetween.

According to the present invention, it is possible to achieve both narrowing and beam steering without switching the antenna that emits radio waves according to the radiation direction.

The figure which shows the specific example of the structure of the phased array antenna system 100 of 1st Embodiment. The figure which shows the specific example of the cross section of the phased array antenna system 100 of 1st Embodiment. The figure which shows the specific example of the equivalent model for demonstrating the effect which the phased array antenna system 100 of 1st Embodiment plays. Explanatory drawing explaining the state of propagation of the radiated radio wave radiated by the patch element 12 in the phased array antenna system 100 of 1st Embodiment. An explanatory diagram illustrating the narrowing of the beam realized by the phased array antenna system 100 of the first embodiment by a system equivalent model. Explanatory drawing explaining beam steering by a phased array antenna system 100 of 1st Embodiment. Explanatory drawing explaining the condition of the specific simulation of the beam steering by the phased array antenna system 100 of 1st Embodiment. The figure which shows the concrete simulation result of the beam steering by the phased array antenna system 100 of 1st Embodiment. The figure which shows the specific example of the structure of the phased array antenna system 100a of 2nd Embodiment. The figure which shows the result of having simulated the radiation pattern of the radio wave radiated by the phased array antenna system 100a of the 2nd Embodiment. The figure which shows the specific example of the structure of the phased array antenna system 100b in 3rd Embodiment. The top view which shows the specific example of the structure of the planar phased array antenna 1b in 3rd Embodiment. The figure which shows the specific simulation result which shows the frequency dependence of a distance H and a gain in 3rd Embodiment. The figure which shows the specific example of the structure of the phased array antenna system 100c of 4th Embodiment. Explanatory drawing explaining the conventional method of narrowing a beam by a convex lens. The figure which shows the ray of the radio wave in the state which narrowed beam by the conventional narrowing beam method by a convex lens, and further steered to the left. Explanatory drawing explaining the method of realizing beam steering by switching antennas.

(First Embodiment)
FIG. 1 is a diagram showing a specific example of the configuration of the phased array antenna system 100 of the first embodiment.
The phased array antenna system 100 includes a planar phased array antenna 1 and a dielectric plate 2. The planar phased array antenna 1 radiates radio waves in a predetermined direction. The dielectric plate 2 reflects a part of the radio wave radiated by the planar phased array antenna 1 and transmits a part of the radio wave. The phased array antenna system 100 radiates narrow-beamed radio waves by multiple reflections of radio waves generated between the planar phased array antenna 1 and the dielectric plate 2.

The planar phase array antenna 1 is a two-dimensional planar phase array antenna provided with a plurality of antenna elements that radiate radio waves toward the dielectric plate 2 in the same plane. The user can change the direction of the radio wave emitted by the planar phased array antenna 1 by setting the phase of the voltage or current applied to each antenna element to a different phase for each antenna element, as in the case of a general phased array antenna. Can be done. The antenna element is, for example, a microstrip antenna. Hereinafter, the radio wave radiated by the planar phased array antenna 1 is referred to as a radiated radio wave. The direction in which the planar phased array antenna 1 emits radiated radio waves is the broadside direction. The planar phased array antenna 1 has substantially the same shape as a flat plate. Hereinafter, the axis connecting the center of the planar phased array antenna 1 and the center of the dielectric plate 2 is defined as the Z axis, and the direction in which the dielectric plate 2 is viewed from the planar phased array antenna 1 is defined as the positive direction of the Z axis. The planar phased array antenna 1 has substantially the same shape as the flat plate and is arranged parallel to the XY plane perpendicular to the Z axis.

The dielectric plate 2 is a flat plate-shaped dielectric arranged parallel to the XY plane at a distance S in the Z-axis direction from the planar phased array antenna 1. That is, the dielectric plate 2 and the planar phased array antenna 1 are parallel to each other. The distance S is substantially the same as the length of 1/2 of the wavelength in the free space of the radiated radio wave. The thickness t of the dielectric plate 2 in the Z-axis direction is substantially the same as the length of 1/4 of the wavelength λd (that is, the so-called in-material wavelength) of the radiated radio wave in the dielectric plate 2. More specifically, when the relative permittivity of the dielectric plate 2 is ε, the wavelength of the radiated radio wave in the free space is λ0, and the relative permeability of the dielectric plate 2 is 1, the dielectric plate 2 is used. The thickness t of is substantially the same as λd / 4 = (λ0 / (ε ^ (1/2))) / 4. Note that ε is a positive value larger than 1. Hereinafter, for the sake of simplicity, it is assumed that the relative magnetic permeability of the dielectric plate 2 is 1.

FIG. 2 is a diagram showing a specific example of a cross section of the phased array antenna system 100 of the first embodiment.

The planar phased array antenna 1 includes a dielectric layer 11, a patch element 12, and a ground conductor plate 13. The dielectric layer 11 is a flat plate-shaped dielectric parallel to the XY plane. The thickness of the dielectric layer 11 is negligibly thin as compared with the wavelengths of the radiated radio waves in the dielectric layer 11 and in the free space. The dielectric layer 11 has substantially the same strength of interaction with radio waves as 0.

The patch element 12 is an antenna element and is located on one surface of the dielectric layer 11 perpendicular to the Z axis. The patch element 12 is located at a position facing the dielectric plate 2. The thickness of the patch element 12 in the Z-axis direction is negligibly thin as compared with the wavelength of the radiated radio wave in the patch element 12 and in the free space. The patch element 12 radiates the radiated radio wave toward the space in the positive direction of the Z axis. For example, the patch element 12 radiates radiated radio waves substantially in parallel in the positive direction of the Z axis. Hereinafter, for the sake of simplicity, it is assumed that the patch element 12 emits radiated radio waves substantially in parallel in the positive direction of the Z axis. Since the patch element 12 emits radiated radio waves substantially parallel to the Z-axis positive direction, the radiated radio waves are incident on the dielectric plate 2 substantially vertically.

The ground conductor plate 13 is located on the other surface of the dielectric layer 11 perpendicular to the Z axis. The thickness of the ground conductor plate 13 in the Z-axis direction is negligibly thin compared to the wavelength of the radiated radio wave in the ground conductor plate 13 and in the free space. The ground conductor plate 13 is a conductor, and the transmittance for the radiated radio wave is substantially the same as 0%, and the radiated radio wave is reflected at a predetermined reflectance. It is desirable that the reflectance of the ground conductor plate 13 is substantially the same as 100%. Hereinafter, for the sake of simplicity of explanation, it is assumed that the reflectance of the ground conductor plate 13 is 100%.

Here, the effect caused by the thickness t of the dielectric plate 2 being substantially the same as 1/4 of the wavelength λd in the substance will be described.

The radiated radio wave incident on the dielectric plate 2 is partially reflected on the lower surface of the dielectric plate 2 (this reflection is a fixed end reflection) regardless of the thickness t of the dielectric plate 2, and a part is dielectric. It propagates inside the body plate 2. The lower surface of the dielectric plate 2 is a surface of the dielectric plate 2 that opposes the patch element 12. In FIG. 2, the lower surface of the dielectric plate 2 is a surface of the dielectric plate 2 perpendicular to the Z axis in the negative direction. The radiated radio wave propagating inside the dielectric plate 2 is also partially reflected on the upper surface of the dielectric plate 2 (this reflection is free-end reflection), and a part is transmitted through the dielectric plate 2. The upper surface of the dielectric plate 2 is a surface of the surface of the dielectric plate 2 that is parallel to the lower surface of the dielectric plate 2 and is located on the opposite side of the dielectric plate 2. In FIG. 2, the upper surface of the dielectric plate 2 is a surface perpendicular to the Z axis of the dielectric plate 2 in the positive direction.

Hereinafter, the radiated radio wave emitted from the patch element 12, incident on the lower surface of the dielectric plate 2, reflected on the lower surface of the dielectric plate 2, and then incident on the patch element 12 is referred to as a radiated radio wave R1.
Hereinafter, the radiated radio wave emitted from the patch element 12, propagates inside the dielectric plate 2, is incident on the upper surface of the dielectric plate 2, is reflected on the upper surface of the dielectric plate 2, and then is incident on the patch element 12. It is called radiated radio wave R2.

The radiated radio wave R1 and the radiated radio wave R2 have different optical path lengths because the radiated radio wave R2 propagates inside the dielectric plate 2. The difference in the optical path length between the radiated radio wave R1 and the radiated radio wave R2 is 2εt because it occurs depending on whether or not each radio wave propagates inside the dielectric plate 2.
Further, as described above, the reflection on the upper surface of the dielectric plate 2 is free-end reflection, and the reflection on the lower surface is fixed-end reflection. Therefore, when t = λd / 4, the phases of the radiated radio wave R1 and the radiated radio wave R2 in the path propagating from the dielectric plate 2 to the patch element 12 are in phase.

If the phases of the radiated radio wave R1 and the radiated radio wave R2 in the path propagating from the dielectric plate 2 to the patch element 12 are opposite to each other, the radiated radio wave R1 and the radiated radio wave R2 cancel each other out. This means that the patch element 12 cannot emit radio waves. Further, when the phases of the radiated radio wave R1 and the radiated radio wave R2 in the path propagating from the dielectric plate 2 to the patch element 12 are not in the opposite phase but not in the same phase, the radiated radio wave R1 and the radiated radio wave R1 are compared with the same phase. The coherent property with the radiated radio wave R2 is reduced.

In general, the higher the coherent property, the stronger and narrower the radio wave is generated like a laser beam. Therefore, as described above, the phased array antenna system 100 in the first embodiment having the thickness t = λd / 4 of the dielectric plate 2 can strongly narrow the emitted radio wave.

Further, when the coherent property of the radiated radio wave R1 and the radiated radio wave R2 is high, the radiated radio wave R1 and the radiated radio wave R2 may be regarded as the same radio wave. This means that when analyzing the radio waves generated by the phased array antenna system 100, the analyst does not need to distinguish between the reflection by the upper surface and the reflection by the lower surface of the dielectric plate 2. Therefore, in the analysis, the analyst can approximate the dielectric plate 2 to a thin film having no thickness (hereinafter referred to as "equivalent reflective film"). The equivalent reflective film is a film having no thickness, which is located at the same position as the lower surface of the dielectric plate 2 and reflects a part of the incident radio wave and transmits a part of the incident radio wave.

FIG. 3 is a diagram showing a specific example of an equivalent model for explaining the effect of the phased array antenna system 100 of the first embodiment. Hereinafter, an equivalent model for explaining the effect of the phased array antenna system 100 will be referred to as a system equivalent model.

First, the patch element 12 in the system equivalent model will be described. The point representing the equivalent wave source shown in FIG. 3 is an equivalent model of the patch element 12. As described above, the patch element 12 emits radiated radio waves substantially parallel to the positive direction of the Z axis. Therefore, in the phased array antenna system 100 according to the first embodiment, the propagation distance of the radio waves in the X-axis direction and the Y-axis direction is negligible as compared with the propagation distance in the Z-axis direction. Further, as described above, the thickness of the patch element 12 is so thin that it can be ignored as compared with the wavelength of the radiated radio wave in the patch element 12 and the free space. This means that the size of the patch element 12 may be ignored in the analysis of the radio wave in the phased array antenna system 100 of the first embodiment.
In this way, the size of the patch element 12 in the system equivalent model may be ignored. Therefore, in the system equivalent model, the equivalent model of the patch element 12 is represented as a point having no size, as shown in FIG. The equivalent wave source is located at the same position as the center position of the patch element 12.

Next, the ground conductor plate 13 in the system equivalent model will be described. The ground conductor plate 13 in the system equivalent model is the XY plane on which the equivalent wave source is located. That is, the XY plane on which the equivalent wave source is located in the system equivalent model reflects 100% of the radio waves incident from the positive direction of the Z axis, similarly to the ground conductor plate 13. Hereinafter, the XY plane in the system equivalent model is referred to as an equivalent conductor plate.

The dielectric layer 11 does not exist in the system equivalence model. This is because the thickness of the dielectric layer 11 is negligibly thin compared to the wavelength of the radiated radio wave in the patch element 12 and the free space, and the strength of the interaction with the radio wave is substantially the same as 0. ..

In the system equivalent model, the dielectric plate 2 is an equivalent reflective film.
In the system equivalent model, the distance between the equivalent reflective film and the equivalent wave source is the distance S.
The effect of the phased array antenna system 100 can be explained by such a system equivalent model.

Next, the narrowing of the beam by the phased array antenna system 100 of the first embodiment will be described with reference to FIGS. 4 and 5.

In addition, in FIG. 4 below, for the sake of simplicity, the state of propagation of radiated radio waves is divided into several steps and explained step by step, but in an actual physical phenomenon, all steps are within substantially the same time. get up.

FIG. 4 is an explanatory diagram illustrating a state of propagation of radiated radio waves radiated by the patch element 12 in the phased array antenna system 100 of the first embodiment.

The equivalent wave source emits radiated radio waves in the positive direction of the Z axis. Hereinafter, for the sake of simplicity, the time point at which the equivalent wave source radiates the radiated radio wave in the positive direction of the Z axis is referred to as a time point t0. The radiated radio wave emitted by the equivalent wave source is incident on the point P0 on the equivalent reflective film. A part of the radiated radio wave incident on the point P0 of the equivalent reflective film is reflected. The radiated radio wave reflected at the point P0 of the equivalent reflective film is incident on the equivalent conductor plate. Radiated radio waves incident on the equivalent conductor plate are reflected. The radiated radio wave reflected by the equivalent conductor plate re-enters the equivalent reflective film. The point P1 is a point in FIG. 4 where the radiated radio wave is incident on the equivalent reflective film again. Hereinafter, the time point at which the radiated radio wave is incident on the equivalent reflective film for the second time is referred to as time point t1. The distance that the radiated radio wave propagated from the time point t0 to the time point t1 is 3S.
In the figure, the points P0 and P1 are drawn as if they have a finite distance for the sake of simplicity, but in reality, the distance between the points P0 and the points P1 is substantially the same as 0. .. Similarly, the position of the virtual wave source in the X-axis direction or the Y-axis direction is substantially the same as the position of the equivalent wave source in the X-axis direction or the Y-axis direction.

Up to this point, the case where the radiated radio wave is reflected once by the equivalent reflective film has been described, but the same applies to the case where the radiated radio wave is reflected N times.
Specifically, when the radiated radio wave is reflected N times (N is an integer of 1 or more) by the equivalent reflective film, the distance _{that such the radiated radio wave propagates from the time point t 0} to the time point t _{N is N.} × 2S + S = (2N + 1) S. t _N is the time when the radiated radio wave reflected N times by the equivalent reflective film reaches the transmitted reflective film at the (N + 1) th time. Hereinafter, the point of the equivalent reflective film where the radiated radio wave is incident at the (N + 1) th time is referred to as a point _PN . The distance between each point of the point P _{0 ~} point P _N is substantially the same to zero.

Here, the concepts of a virtual wave source and a virtual radio wave will be described. A virtual wave source is a virtual wave source located at a position separated from the equivalent reflective film by a predetermined distance, which is an integral multiple of S in the negative direction of the Z axis, and emits virtual radio waves in the positive direction of the Z axis. It is a virtual wave source. Virtual Telecommunications has the same frequency as the radio wave radiated, at time t ₀ is emitted in the same phase as the radiated wave is a virtual wave that is not reflected and absorbed by the dielectric plate 2 and the ground conductor plate 13.

The virtual wave source and the virtual radio wave do not have a substance, but are virtual concepts for explaining the effect of the complicated multiple reflection of the radiated radio wave in the phased array antenna system 100. FIG. 4 shows a virtual wave source and a virtual radio wave when N = 1. The virtual wave source in FIG. 4 is a virtual wave source located at a position separated from the equivalent reflective film by 3S in the negative direction of the Z axis.

Hereinafter, a virtual wave source located at a position separated from the equivalent reflective film by a distance (2N + 1) S in the negative direction of the Z axis is referred to as a Nth virtual wave source. Hereinafter, the virtual radio wave radiated by the Nth virtual wave source is referred to as the Nth virtual radio wave. Similar to the positional relationship between the virtual wave source and the equivalent wave source in FIG. 4, the position of the Nth virtual wave source in the X-axis direction or the Y-axis direction is substantially the same as the position of the equivalent wave source in the X-axis direction or the Y-axis direction.

The use of such a virtual wave source and the virtual current time t _N subsequent radio wave radiated frequency, phase and wave number vectors are described to be equivalent to the N virtual radio.

This is because the radiated radio wave and the virtual radio wave have the same frequency, are radiated from the equivalent wave source or the virtual wave source in the same phase at _{the time point t 0 , have the same propagation distance from the time point t 0} to the time point t _N , and have the same propagation distance at the point P. This is because it is incident on _{N from the same direction.}

Therefore, the effect produced by the multiple reflections of the radiated radio waves in the phased array antenna system 100 of the first embodiment can be explained by a virtual wave source according to the number of reflections generated in the equivalent reflection film.

Specifically, the effect of the phased array antenna system 100 can be explained by a system equivalent model that models the phased array antenna system 100 using the concept of a virtual wave source.

FIG. 5 is an explanatory diagram illustrating the narrowing of the beam realized by the phased array antenna system 100 of the first embodiment by a system equivalent model.

In the phased array antenna system 100, in principle, the radiated radio wave is reflected infinitely by the dielectric plate 2. This is equivalent to the existence of an infinite number of virtual wave sources. Therefore, in the system equivalent model, there are an infinite number of virtual wave sources in the negative direction of the Z axis. In the system equivalence model, each infinite number of virtual wave sources is arranged in the negative direction of the Z axis for each distance of 2S.

Here, consider that S is 1/2 of the wavelength. Since S is ½ of the wavelength, the phases of the radiated radio wave and the virtual radio wave are in phase on the equivalent reflection surface. Therefore, the radiated radio wave and the virtual radio wave strengthen each other, and a radio wave having high coherent property is generated.

An antenna system in which wave sources are periodically arranged in the uniaxial direction at wavelength intervals in this way is generally called an end fire array. An endfire array is an antenna system that produces radio waves with a narrow beam.

It can be said that the phased array antenna system 100 of the first embodiment is a virtual end fire array in which virtual wave sources are periodically arranged in one axial direction at wavelength intervals instead of a real wave source. Therefore, the phased array antenna system 100 of the first embodiment configured as described above is similar to the end fire array because the planar phased array antenna 1 and the dielectric plate 2 are provided at a distance of 1/2 of the wavelength. In addition, it is possible to realize a narrow beam of radio waves. In FIG. 5, the narrow beam radio wave is a radio wave narrowed by the phased array antenna system 100.

FIG. 6 is an explanatory diagram illustrating beam steering by the phased array antenna system 100 of the first embodiment. So far, for the sake of simplicity, it has been assumed that the patch element 12 emits radiated radio waves substantially in parallel in the positive direction of the Z axis. When the phased array antenna system 100 performs beam steering of radio waves, the patch element 12 emits radiated radio waves in a direction forming an angle with the Z axis. Therefore, in FIG. 6, it is assumed that the patch element 12 not only radiates the radiated radio wave substantially in parallel in the positive direction of the Z axis, but also radiates the radiated radio wave in the direction at an angle with the Z axis.

First, beam steering by the phased array antenna system 100 of the first embodiment will be described. At the time of beam steering, the planar phase door tray antenna 1 emits radiated radio waves in a direction forming an angle with the Z axis, not parallel to the Z axis direction. Hereinafter, the angle formed by the Z-axis in the direction in which the planar phased array antenna 1 emits radiated radio waves is defined as θ. In this case, since the direction of the radiated radio wave is the direction of the angle θ, the radio wave radiated by the phased array antenna system 100 is also radiated in the direction of the angle θ. In this way, the phased array antenna system 100 can realize beam steering.

Next, it will be described that a narrow beam can be realized even when the planar phased array antenna 1 emits radiated radio waves in the direction of the angle θ. Even when the planar phased array antenna 1 emits radiated radio waves in a direction not parallel to the Z-axis direction, if the angle θ is within a predetermined range, the propagation path of the radiated radio waves is as shown in FIG. It can be approximated to the propagation path described. Therefore, when the planar phased array antenna 1 radiates radiated radio waves in the direction of the angle θ within a predetermined angle range, the phased array antenna system 100 can narrow the radio waves.

As described above, the phased array antenna system 100 of the first embodiment radiates the beam-steered radio waves as shown in FIG. 6 in a narrow beam state. In FIG. 6, the narrow-steered radio wave is a narrow-beamed and beam-steered radio wave.

Hereinafter, FIGS. 7 and 8 show the simulation results of beam steering by the phased array antenna system 100 of the first embodiment.

FIG. 7 is a diagram illustrating conditions for specific simulation of beam steering by the phased array antenna system 100 of the first embodiment. The simulation was carried out under the condition that the relative permittivity of the dielectric plate was 10.2, S = 15 mm, and the thickness of the dielectric plate was t = 3 mm. Further, in the simulation, four patch elements 12 were arranged at equal intervals in the uniaxial direction. The distance between the center points of the adjacent patch elements 12 is substantially the same at 0.5 wavelength.

FIG. 8 is a diagram showing a specific simulation result of beam steering by the phased array antenna system 100 of the first embodiment. The frequency of the radio wave in the simulation is 10 GHz.

FIG. 8 (a) shows the radiation pattern of the steered radio wave. FIG. 8B shows the radiation pattern of unsteered radio waves. Both FIGS. 8A and 8B show that when the dielectric plate 2 is present, a narrower beam radio wave is emitted than when the dielectric plate 2 is not present.
FIG. 8 shows that the phased array antenna system 100 of the first embodiment realizes beam steering of about 16 °. Further, FIG. 8 shows that the beam-steered radio wave is narrowed.

In the phased antenna system 100 of the first embodiment configured in this way, the distance between the planar phased antenna 1 and the planar phased array antenna 1 is substantially the same as 1/2 of the wavelength of the radio wave in the free space. A dielectric plate 2 having substantially the same thickness as 1/4 of the wavelength in the free space is provided at the position. Therefore, a virtual end fire array can be realized, and narrowing the beam and beam steering can be achieved at the same time with a simpler configuration than the conventional antenna system.

The patch element 12 may radiate radiated radio waves in any way. The patch element 12 may emit radiated radio waves by being excited by, for example, an AC power source.

(Second embodiment)
FIG. 9 is a diagram showing a specific example of the configuration of the phased array antenna system 100a of the second embodiment.
The phased array antenna system 100a of the second embodiment is different from the phased array antenna system 100 of the first embodiment in that a plurality of dielectric plates 2 are provided in one axial direction instead of one.
Hereinafter, the dielectric plate 2 in the second embodiment is referred to as a dielectric plate 2a. The dielectric plates 2a in the second embodiment are sequentially arranged at predetermined intervals in the Z-axis direction. Hereinafter, when the dielectric plates 2a are distinguished from each other, it is referred to as a dielectric plate 2am (m is an integer of 1 or more).

The dielectric plate 2a-m is a flat plate-shaped dielectric arranged parallel to the XY plane at a distance m × S in the positive direction of the Z axis from the planar phased array antenna 1. That is, the dielectric plate 2am and the planar phased array antenna 1 are parallel to each other. The relative permittivity and the relative magnetic permeability of the dielectric plate 2a and the thickness of the dielectric plate 2a in the Z-axis direction are the same as those in the first embodiment.

The phased array antenna system 100a of the second embodiment includes a plurality of dielectric plates 2a. Therefore, the number of propagation paths to which radio waves are reflected increases as compared with the phased array antenna system 100 of the first embodiment. Therefore, the radio wave can be narrowed even more strongly than the phased array antenna system 100 of the first embodiment.

FIG. 10 is a diagram showing the result of simulating the radiation pattern of the radio wave emitted by the phased array antenna system 100a of the second embodiment. FIG. 10 shows the results when the planar phased array antenna 1 is provided with 2 × 6 antenna elements and emits radio waves having a frequency of 9 GHz.

FIG. 10A shows the results when there is no dielectric plate 2a and when there is only one. FIG. 10B shows the results of the case where the dielectric plate 2a is one and the case where the dielectric plate 2a is two. FIG. 10 shows that the power half-value angle is 27 ° in the absence of the dielectric plate 2a. FIG. 10 shows that when there is one dielectric plate 2a, the half-value angle of power is 20 °. FIG. 10 shows that when there are two dielectric plates 2a, the power half-value angle is 17 °.
As described above, as the number of the dielectric plates 2a increases, the radio wave radiated by the phased array antenna system 100a of the second embodiment becomes narrower.

The phased array antenna system 100a of the second embodiment configured as described above includes a planar phased array antenna 1 and a plurality of dielectric plates 2a. Therefore, it is possible to increase the propagation path through which the radio wave is reflected, and it is possible to realize a narrower beam than the phased array antenna system 100 of the first embodiment.

(Third embodiment)
FIG. 11 is a diagram showing a specific example of the configuration of the phased array antenna system 100b according to the third embodiment.
The phased array antenna system 100b includes a planar phased array antenna 1b and dielectric plates 2a-1 and 2a-2.
Hereinafter, those having the same functions as those in FIGS. 1, 2 or 9 are designated by the same reference numerals and the description thereof will be omitted.

The planar phased array antenna 1b includes a dielectric layer 11, a plurality of patch elements 12, and a ground conductor plate 13.

FIG. 12 is a top view showing a specific example of the configuration of the planar phased array antenna 1b according to the third embodiment.
The dielectric layer 11, the long side in the XY plane length L _S, the short side has a rectangular shape of length W _S. Hereinafter, for the sake of simplicity, it is assumed that the long side of the dielectric layer 11 is parallel to the X axis and the short side is parallel to the Y axis. Patch element 12 is a square shape with one side _{L d} in the XY plane. L _d is substantially the same as 1/4 of the wavelength in the free space of the radiated radio wave, and is 1/4 or more the length of the wavelength in the free space of the radiated radio wave.

One side of each patch element 12 is parallel to one side of the dielectric layer 11. The plurality of patch elements 12 are located in a matrix parallel to each side of the dielectric layer 11. The distance between the centers of each patch element 12 is a predetermined length d. The length d is substantially the same as ½ of the wavelength of the radiated radio wave in the free space.
The distance H between the center point of each patch element 12 and one side of the dielectric layer 11 closest to each patch element 12 satisfies the following equations (1) and (2).

V _W is the number of patch elements 12 in the axial direction parallel to the short side of the dielectric layer 11. _VL is the number of patch elements 12 in the axial direction parallel to the long side of the dielectric layer 11.
In FIG. 12, V _W is 2 and _VL is 6.
The distance H is a length that reflects the length of the margin of the dielectric layer 11. For the sake of simplicity, the distance H is hereinafter referred to as the margin H.

FIG. 13 is a diagram showing specific simulation results showing the frequency dependence of the distance H and the gain in the third embodiment. FIG. 13 is a simulation result performed under the condition of _{L s = 135 mm. Λ s} in FIG. 13 is the wavelength in the free space of the radio wave whose frequency is the center frequency in the simulation. The center frequency in the simulation is 10 GHz.

The simulation results shown in FIG. 13 show that the margin H is (2/4) × λ _s , the margin H is (3/4) × λ _s , and the margin H is (4/4). The relationship between the gain and the frequency is shown in the case where × λ _s and the case where the margin H is (5/4) × λ _s.

The simulation results shown in FIG. 13 show that the margin H is (3/4) × λ _s , the margin H is (4/4) × λ _s , and the margin H is (5/4) × λ s. It is shown that the fluctuation range of the gain with respect to the change of frequency is smaller than in a certain case. Further, the simulation result shown in FIG. 13 shows that, for example, when the margin H is made smaller than (3/4) × λ _{s , such as (2/4) × λ s} , it is within the observed frequency range. It is shown that there is no decrease in the overall gain of. FIG. 13 Therefore, the simulation results of FIG. 13 show that the phased array antenna system 100b having a _{margin H of (3/4) × λ s is optimal for realizing a narrow beam.} When the margin H is _{smaller than (3/4) × λ s} , the opening surface size cannot be sufficiently obtained and the gain decreases. Further, when the margin H is _{larger than (3/4) × λ s} , the band is narrowed and a minimum value with a low gain appears. The reason for this is that a resonance mode is set in the dielectric layer 11.

The shape of the dielectric layer 11 and the shape of the patch element 12 do not necessarily have to be quadrangular. Further, the margin H does not necessarily have to be the distance between one side of the dielectric layer 11 having a rectangular shape and the center point of the patch element 12. The margin H may be any distance as long as it is the distance between the center point of the patch element 12 and the portion closest to the center point of the patch element 12 on the circumference of the dielectric layer 11.
The shape of the dielectric layer 11 and the shape of the patch element 12 may be, for example, circular. In such a case, the margin H is the shortest distance connecting the center point of the patch element 12 and the circumference of the dielectric layer 11.

(Fourth Embodiment)
FIG. 14 is a diagram showing a specific example of the configuration of the phased array antenna system 100c according to the fourth embodiment.
The phased array antenna system 100c of the fourth embodiment is different from the phased array antenna system 100 of the first embodiment in that it includes a negative meniscus lens 3.
The negative meniscus lens 3 is a negative meniscus lens. The negative meniscus lens 3 is located on the opposite side of the planar phased array antenna 1 with the dielectric plate 2 interposed therebetween. The negative meniscus lens 3 increases the angle formed by the Z-axis of the narrow-steered radio wave, which is a steered radio wave. In FIG. 14, the Z axis is not beam steered and is parallel to the direction in which the narrowed beam is propagated.

The phased array antenna system 100c of the fourth embodiment configured in this way can increase the steering range as compared with the phased array antenna systems 100, 100a and 100b. Increasing the steering range means widening the angle between the beam-steered radio waves and the unbeam-steered radio waves.

As described with reference to FIGS. 4 to 5, the phased array antenna systems 100, 100a and 100b realize a narrow beam by an operating principle different from that of the conventional antenna system. Further, as described in FIG. 6, the phased array antenna systems 100, 100a and 100b also realize beam steering. However, in the phased array antenna systems 100, 100a and 100b, since the radio wave is narrowed, there is a problem that the narrower the beam is, the narrower the steering range is. Since the phased array antenna system 100c according to the fourth embodiment includes the negative meniscus lens 3, it is possible to widen the steering range and solve the problem that the steering range is narrowed.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes designs and the like within a range that does not deviate from the gist of the present invention.

1 ... Flat phased array antenna, 1b ... Flat phased array antenna, 2 ... Dielectric plate, 2a ... Dielectric plate, 3 ... Negative meniscus lens, 11 ... Dielectric layer, 12 ... Patch element, 13 ... Ground conductor plate , 100 ... Phased array antenna system, 100a ... Phased array antenna system, 100b ... Phased array antenna system, 100c ... Phased array antenna system

Claims (3)

A plurality of antenna elements that emit radio waves are provided in the same plane, and the position is parallel to the same plane and the distance from the same plane is negligibly shorter than the wavelength in the free space of the radio wave. A plane type phased array antenna provided with a ground conductor plate that reflects the radio waves in the plane
Each said a parallel flat plate shaped dielectric flush, a plurality of dielectric plates is a dielectric located broadside direction of the antenna element,
Equipped with
The thickness of the plurality of the dielectric plate has a substantially identical to 1/4 of the material in the wavelength in the dielectric of each of said radio wave,
The distance between each surface of the plurality of dielectric plates facing the antenna element and the surface provided with the antenna element are different from each other and are approximately ½ of the natural number of the wavelength in the free space of the radio wave. Is the same,
Phased array antenna system. A plurality of antenna elements that emit radio waves are provided in the same plane, and the positions are parallel to the same plane and the distance from the same plane is negligibly shorter than the wavelength in the free space of the radio waves. A plane type phased antenna having a flat plate-shaped dielectric layer parallel to the same plane in a space sandwiched between the ground conductor plate that reflects the radio wave in the plane and the plane having the same plane and the ground conductor plate. With the antenna,
A dielectric plate that is a flat plate-shaped dielectric parallel to the same plane and is a dielectric located in the broadside direction of the antenna element.
Equipped with
The thickness of the dielectric plate is substantially the same as 1/4 of the wavelength in the substance of the dielectric of the radio wave.
Wherein a surface facing to the antenna elements of the dielectric plate, the distance between the surface provided with the antenna elements, Ri substantially equal der to 1/2 of the wavelength in free space of the radio wave,
Let the distance between the center point of each antenna element and the peripheral portion of the dielectric layer closest to each antenna element be a margin H, and H is 3 / of the wavelength in the free space of the radio wave. Approximately the same as 4
Phased array antenna system. A plurality of antenna elements that emit radio waves are provided in the same plane, and the position is parallel to the same plane and the distance from the same plane is negligibly shorter than the wavelength in the free space of the radio wave. A plane type phased array antenna provided with a ground conductor plate that reflects the radio waves in the plane
A dielectric plate that is a flat plate-shaped dielectric parallel to the same plane and is a dielectric located in the broadside direction of the antenna element.
A negative meniscus lens located on the opposite side of the planar phased array antenna across the dielectric plate,
Equipped with
The thickness of the dielectric plate is substantially the same as 1/4 of the wavelength in the substance of the dielectric of the radio wave.
The distance between the surface of the dielectric plate facing the antenna element and the surface provided with the antenna element is substantially the same as ½ of the wavelength in the free space of the radio wave.
Phased array antenna system.

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