KR102039914B1 - Controlled lens antenna apparatus and system - Google Patents

Abstract

Examples relate to microelectronics. For example, compact antenna devices are applied in mobile communications and other equipment operating within the millimeter range. The controlled lens antenna apparatus may comprise antenna elements in an integrated circuit configured to transmit beams. The apparatus may also include a dielectric lens antenna configured to generate plane waves based on the transmitted beams. The apparatus may also include a plate configured to refract the generated plane wave at any angle.

Description

CONTROLLED LENS ANTENNA APPARATUS AND SYSTEM}

The following description relates to a compact controlled lens antenna that enables continuous directivity variation in mobile communications equipment operating within the millimeter range.

This application claims the benefit of the priority of Russian Patent Application No. 2012-144224, filed October 17, 2012 with the Russian Intellectual Property Office, the entire disclosure of which is incorporated herein by reference for all purposes. do.

In the development and manufacture of semi-conductor integrated circuits (ICs), one of the many focuses of recent years has been to reduce the size of ICs by reducing their size while increasing the number of components integrated in the IC. The goal was to increase the IC's package density and provide the maximum operating frequency. The production of high-frequency wide-band ICs for both commercial use and consumer electronics equipment is economical with the advent of silicon ICs with greater functionality on higher frequencies at smaller dimensions and lower cost. Justified. IC-based high-frequency wide-band devices currently operate on small distances within the millimeter range of order from 24 GHz to 60 GHz and automotive radars operating within the range of 24 GHz to 77 GHz. Applied in automobile radar. Such devices are attractive because they are designed to operate at "millimeter-wave" frequencies (3 to 300 gigahertz) or at frequencies close to the "millimeter-wave" frequencies. Cellular networks have always occupied lower bands on the spectrum, and carrier waves of tens of centimeters long (hundreds of megahertz) of the lower bands on this spectrum easily pass around the obstacles and through the air. However, the overuse of these spectra has made it difficult for operators to obtain more from these spectra. Currently, the operating frequencies of commercial communications and radar applications have reached the upper range limit of the radio band and extended to millimeter waves.

Ultra-compact antennas have been developed based on ICs operating within the millimeter range. However, one of the many drawbacks of existing ultra-compact antennas is that existing ultra-compact antennas only allow the performance of discrete directional switching. Smooth scanning within known solutions requires an increase in the number of antennas on the IC, leading to an increase in the area of the IC and leading to the production of larger and more expensive ICs.

This Summary is provided to introduce a selection of concepts that will be described in more detail in the following detailed description in a simplified form. This Summary is not intended to identify key features or essential features of the embodiments, nor is it intended to be used as an aid in determining the scope of the embodiments.

According to one illustrative example, antenna elements in an integrated circuit configured to transmit beams according to one illustrative example, a dielectric lens antenna configured to generate a plane wave based on the transmitted beams, and the generated plane wave at any angle A controlled lens antenna apparatus is provided that includes a plate configured to be refracted by.

The dielectric lens of the dielectric lens antenna may include a hemisphere and a cylindrical continuation, and may be formed of a dielectric.

The antenna elements may be located on the planar surface of the cylindrical continuum of the dielectric lens of the dielectric lens antenna.

The dielectric lens antenna may be homogeneous or composite.

인 유전체 렌즈 몸통, 비유전 전도도가

인 유전체 렌즈 필 피스(fill piece) - 상기

는 상기

보다 큼 - 및 비유전 전도도가

인 매칭 유전체 렌즈 커버링(covering) - 상기

은

임 -을 포함할 수 있다.The dielectric lens antenna has a relative dielectric conductivity

Dielectric lens body, non-electrical conductivity

Dielectric Lens Fill Piece-Above

Above

Greater than-and non-dielectric conductivity

In Matching Dielectric Lens Covering-Above

silver

May include-.

The controlled lens antenna device may be formed on a high-resistance semi-conductive substrate.

The dielectric lens antenna may include a dielectric lens body and a dielectric lens fill piece.

일 수 있고, 상기 유전체 렌즈 필 피스는 비유전 전도도가

인 쌍곡면(hyperboloid)의 필 피스일 수 있다.The dielectric constant of the dielectric lens body is

Wherein the dielectric lens fill piece has a non-dielectric conductivity

It may be a fill piece of the hyperboloid.

및

의 의존성은 하기의 수학식 1을 이룰 수 있고,Non-dielectric Conductivities of the Dielectric Lens Antenna

And

The dependency of can be achieved in the following equation 1,

는 쌍곡면의 축들 간의 각도일 수 있다.remind

May be the angle between the axes of the hyperboloid.

The plate may comprise a ceramic plate, two matching plates and contact electrodes having a dielectric conductivity that varies with the applied voltage.

The deviation angle of the plate may be determined according to arcsin ( d / s ), d may be a propagation difference, and S may be a distance between centers of contact electrodes of the deflection plate.

The plate may comprise ferroelectric ceramic plates and corresponding layers.

According to another illustrative example, an antenna element in an integrated circuit configured to transmit beams, a dielectric lens antenna configured to generate a plane wave based on the transmitted beams, wherein the lens of the dielectric lens antenna has a hemisphere having a predetermined radius And a cylindrical continuum having a predetermined length—and a deflection comprising contact electrodes and configured to deflect the generated plane wave at an angle using a relationship between the propagation difference of the beams and the distance between the centers of the contact electrodes. A controlled lens antenna apparatus is provided that includes a plate.

The antenna elements may be located on the planar surface of the cylindrical continuum.

The dielectric lens antenna may be homogeneous or composite.

인 유전체 렌즈 몸통, 비유전 전도도가

인 유전체 렌즈 필 피스(fill piece) - 상기

는 상기

보다 큼 - 및 비유전 전도도가

인 매칭 유전체 렌즈 커버링(covering) - 상기

은

임 -을 포함할 수 있다.The dielectric lens antenna has a non-dielectric conductivity

Dielectric lens body, non-electrical conductivity

Dielectric Lens Fill Piece-Above

Above

Greater than-and non-dielectric conductivity

In Matching Dielectric Lens Covering-Above

silver

May include-.

The dielectric lens antenna may include a dielectric lens body and a dielectric lens fill piece.

일 수 있고, 상기 유전체 렌즈 필 피스는 비유전 전도도가

인 쌍곡면(hyperboloid)의 필 피스일 수 있다.The dielectric constant of the dielectric lens body is

Wherein the dielectric lens fill piece has a non-dielectric conductivity

It may be a fill piece of the hyperboloid.

및

의 의존성은 하기의 수학식 1을 이룰 수 있고,Non-dielectric Conductivities of the Dielectric Lens Antenna

And

The dependency of can be achieved in the following equation 1,

는 쌍곡면의 축들 간의 각도일 수 있다.remind

May be the angle between the axes of the hyperboloid.

The deflection plate may include a ceramic plate, two matching plates, and contact electrodes having a dielectric conductivity that varies with the applied voltage.

The deflection angle of the deflection plate may be determined through arcsin ( d / s ), d may be a propagation difference, and S may be a distance between centers of contact electrodes of the deflection plate.

The deflection plate may comprise ferroelectric ceramic plates and corresponding layers.

Other features and aspects will be apparent from the following detailed description, drawings, and claims.

1 illustrates an example of a lens antenna that is scanned or controlled in a compact lens device, according to one embodiment.
2 illustrates an example of a controlled lens antenna, according to one embodiment.
3 illustrates a declination angle of a controlled lens antenna, according to an embodiment.
4 illustrates a wave source in focus of a hyperboloid, according to one embodiment.
5A and 5B show an antenna radiation pattern of a controlled lens antenna, according to one embodiment.
Throughout the drawings and the detailed description, unless otherwise described, the same figure reference numbers will be understood to refer to the same elements, features, and structures. The relative size and description of these elements may be exaggerated for clarity of explanation and convenience.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

The following detailed description is provided to assist the reader in gaining a comprehensive understanding of the methods, devices, and / or systems described in this document. Accordingly, equivalents of the various modifications, adaptations, and systems, apparatuses, and / or methods described herein may be implied to one of ordinary skill in the art. The progression of processing steps and / or operations is an example, but the sequence of steps and / or operations is not limited to that described herein, and essentially requires steps and / or actions to occur in a particular order. Except as may be known in the art. In addition, descriptions of well-known functions and structures may be omitted for increased clarity and brevity.

According to the described embodiment, a compact lens antenna device is shown that allows for smooth directional changes without increasing the area and manufacturing cost of integrated circuits. In one example, the compact lens apparatus is part of millimeter range systems such as wireless radars and wireless data transmission systems that enable designing compact controlled lens antenna systems with low frequency requirements. Can be used.

The compact lens antenna device may include antenna elements in the IC and a dielectric lens antenna configured to generate plane waves. Antenna elements may be configured to transmit beams. The compact lens antenna device may also include a plate configured to refract the plane wave generated at any angle. The plate may be a deflection plate.

1 illustrates an example of a lens antenna that is scanned or controlled in a compact lens device, according to one embodiment.

In one illustrative example, FIG. 1 shows a schematic of a lens antenna 100 that is scanned or controlled. In one example, a controlled lens antenna can be used in visualization systems. The controlled lens antenna 100 may include a lens 110 and an antenna element 120. Lens 100 may include a hemisphere 112 with radius R and a cylindrical continuum 114 with length L. In one example, lens 110 may be formed of a dielectric. Antenna elements 120 may be located on the planar surface of the cylindrical continuum 114. Each antenna element 120 may transmit signals according to corresponding beams 130. The angular direction of each beam 130 may correspond to X as a shift, distance or displacement of the corresponding antenna element 120 from the focal point 116 of the lens 110, respectively. Can be. By displacing each of the antenna elements 120, scanning in accord with the transmission requirements of the external circuit can be provided. In one example, external circuitry may be used for video transmission from each element of antenna elements 120.

2 illustrates an example of a controlled lens antenna, according to one embodiment.

인 유전체 렌즈 몸통(3.1 및 3.2) 및 비유전 전도도가

인 유전체 렌즈 필 피스(fill piece)(3.4)를 포함할 수 있다.

는

보다 클 수 있다. 유전체 렌즈 안테나(3.1 내지 3.4)는 또한 매칭 유전체 렌즈 커버링(3.3)을 포함할 수 있다. 비유전 전도도는 비유전율(relative permittivity)일 수 있다.The controlled lens antenna of FIG. 2 may include an integrated circuit (IC) 1, antenna elements 2 on the IC 1, dielectric lens antennas 3.1 to 3.4 and deflection plates 4.1 to 4.4. . A controlled lens antenna comprising antenna elements 2 on the IC 1 and dielectric lens antennas 3.1 to 3.4 produces a plane wave. In one example, the dielectric lens antennas 3.1 to 3.4 may be homogeneous or composite. Dielectric lens antennas (3.1 to 3.4) have a dielectric constant

Phosphor Dielectric Lens Body (3.1 and 3.2) and Non-Dielectric Conductivity

Phosphor dielectric lens fill piece (3.4).

Is

Can be greater than Dielectric lens antennas 3.1 to 3.4 may also include a matching dielectric lens covering 3.3. The relative dielectric constant may be relative permittivity.

The plane wave generated by the dielectric lens antennas 3.1 to 3.4 can be refracted by the deflection plates 4.1 to 4.4. The deflection plates 4.1 to 4.4 may comprise, for example, a ceramic plate 4.2, two matching plates 4. 1 and 4.3 and contact electrodes 4.4. The dielectric conductivity of the ceramic plate 4.2 can be changed in accordance with a given applied voltage. The dielectric conductivity may be permittivity. The predetermined applied voltage may be a voltage applied to the ceramic plate 4.2 by the contact electrodes 4.4. The deflection plates 4.1 to 4.4 can be configured to deflect the plane wave generated at any angle using the relationship between the propagation difference of the beams and the distance between the centers of the contact electrodes 4.4. The angle of deflection of the deflection plates 4.1 to 4.4 can be determined using the relationship of arcsin ( d / s ) below. d may be a propagation difference of beams. S may be the distance between the centers of the contact electrodes. 3 illustrates a declination angle of a controlled lens antenna, according to an embodiment. Therefore, the declination angle can be expressed by Equation 3 below.

는 편각일 수 있다. h는 세라믹 판(4.2)의 두께일 수 있다.

및

는 다양한 전압들의 영향 하에 세라믹 판(4.2)의 다양한 부분들의 비유전 전도도들일 수 있다. s는 접촉 전극들의 중심들 간의 거리일 수 있다. 도 5a 및 도 5b는 일 실시예에 따른, 제어되는 렌즈 안테나의 안테나 지향성도(radiation pattern)를 나타낸다.here,

May be a declination. h may be the thickness of the ceramic plate 4.2.

And

Can be the dielectric constants of the various parts of the ceramic plate 4.2 under the influence of various voltages. s may be the distance between the centers of the contact electrodes. 5A and 5B show an antenna radiation pattern of a controlled lens antenna, according to one embodiment.

인 유전체 렌즈 몸통(3.1 및 3.2) 및 유전체 렌즈 필 피스를 포함할 수 있다. 유전체 렌즈 필 피스는 비유전 전도도가

인 쌍곡면(hyperboloid) 필 피스(3.4)일 수 있다. 쌍곡면 필 피스(3.4)는 제어되는 렌즈 안테나 장치의 면적의 상당한 감소를 가능하게 하도록 구성될 수 있다. 일 예에서, 구형파를 평면파로 변환하기 위해, 파원은 쌍곡면의 초점 내에 배치될 수 있다(도 4 참조). 도 4에서, F₁ 및 F₂는 쌍곡면의 초점들을 나타낸다. x 및 y는 쌍곡면을 구성하는 점들의 좌표 값들을 나타낸다. 초점 F₂로부터 출발한 파는 쌍곡선 상의 점에서 β-α만큼 굴절될 수 있다. 점선은 상기의 점의 법선일 수 있다. 유전체 렌즈 안테나(3.1 내지 3.4)의 비유전 전도도들

및

의 의존성은 하기의 수학식 4에 의해 표현될 수 있다.According to one embodiment, a controlled lens antenna device on an IC may be formed on a high-resistance semi-conductive substrate. Dielectric lens antennas (3.1 to 3.4) have a dielectric constant

Phosphor dielectric lens body (3.1 and 3.2) and a dielectric lens fill piece. Dielectric lens fill piece has a non-dielectric conductivity

It may be a hyperboloid fill piece (3.4). The hyperbolic fill piece 3.4 can be configured to allow for a significant reduction in the area of the controlled lens antenna device. In one example, to convert a square wave into a planar wave, the wave source may be placed within the focal point of the hyperboloid (see FIG. 4). In FIG. 4, F ₁ and F ₂ represent the focal points of the hyperboloid. x and y represent coordinate values of the points constituting the hyperbolic surface. The wave starting from the focal point F ₂ can be refracted by β-α at points on the hyperbola. The dotted line may be a normal of the above point. Non-dielectric Conductivities of Dielectric Lens Antennas 3.1 to 3.4

And

The dependency of can be expressed by Equation 4 below.

는 쌍곡면 축들 간의 각도일 수 있다. tg는 탄젠트 함수일 수 있다. 예컨대,

인 경우,

일 수 있다. 유전 손실들을 고려하면, 하기의 수학식 5의 관계가 적용될 수 있다.here

May be the angle between the hyperbolic axes. tg may be a tangent function. for example,

If is

Can be. Considering the dielectric losses, the relationship of Equation 5 below can be applied.

인 매칭 유전체 렌즈 커버링(3.3)을 포함할 수 있다. 비유전 전도도

은 하기의 수학식 6에 의해 표현될 수 있다.In addition, the dielectric lens antenna (3.1 to 3.4) has a non-dielectric conductivity

In-matching dielectric lens covering 3.3. Non-dielectric conductivity

Can be expressed by Equation 6 below.

According to an alternative configuration, the deflection plates 4.1 to 4.4 may comprise ferroelectric ceramic plates and matching or corresponding layers. The dielectric conductivity of ferroelectric ceramic plates can be controlled by the voltage applied.

Although this document contains specific examples, it is conventional in the art that various changes may be made within the form and details within embodiments that fall within the spirit and scope of the claims and their equivalents. It will be self-evident to those who have knowledge. The examples described in this document should be considered within a descriptive sense and not for the purposes of limitation. Descriptions of features or aspects in each example are to be considered applicable to similar features or aspects in the other examples. Performing the described techniques in different order and / or replacing or supplementing by different combinations of components in the described system, architecture, device or circuit and / or equivalents of other components or other components (suitable) results can be achieved. Accordingly, the scope of the embodiments is not defined by the detailed description, but is defined by the claims and their equivalents, and all modifications within the scope of the claims and their equivalents are included within this document. Should be interpreted as

Claims (20)

Antenna elements in an integrated circuit configured to transmit beams;
A dielectric lens antenna configured to generate plane waves based on the transmitted beams; And
A plate configured to refract the generated plane wave at an angle
Including,
The dielectric lens antenna,
Non-dielectric conductivity

Dielectric lens body;
Non-dielectric conductivity

Dielectric Lens Fill Piece-Above

Above

Greater than-; And
Non-dielectric conductivity

In Matching Dielectric Lens Covering-Above

silver

Im-
Including,
Controlled lens antenna device. The method of claim 1,
And a dielectric lens of said dielectric lens antenna comprises a hemisphere and a cylindrical continuation and formed of a dielectric. The method of claim 1,
And the antenna elements are located on the planar surface of the cylindrical continuum of the dielectric lens of the dielectric lens antenna. The method of claim 1,
And the dielectric lens antenna is homogeneous or composite. delete The method of claim 1,
The controlled lens antenna device is formed on a high-resistance semi-conductive substrate. Antenna elements in an integrated circuit configured to transmit beams;
A dielectric lens antenna configured to generate plane waves based on the transmitted beams; And
A plate configured to refract the generated plane wave at an angle
Including,
The dielectric lens antenna,
Dielectric lens body; And
A dielectric lens fill piece,
The dielectric constant of the dielectric lens body is

And the dielectric lens fill piece has a non-dielectric conductivity

It is a peel piece of the phosphorus hyperboloid,
Controlled lens antenna device. The method of claim 1,
Non-dielectric Conductivities of the Dielectric Lens Antenna

And

The dependency of the following Equation 1,
[Equation 1]

remind

Is an angle between the axes of the hyperboloid, and tg is a tangent function. The method of claim 1,
The plate may comprise a ceramic plate having a dielectric conductivity that varies with applied voltage;
Two matching plates; And
Contact electrodes
Controlled lens antenna device comprising a. The method of claim 1,
The deviation angle of the plate is determined according to arcsin (d / s), d is a propagation difference, and S is a distance between centers of contact electrodes of the plate. The method of claim 1,
And the plate comprises ferroelectric ceramic plates and corresponding layers. Antenna elements in an integrated circuit configured to transmit beams;
A dielectric lens antenna configured to generate a plane wave based within the transmitted beams, wherein the lens of the dielectric lens antenna comprises a hemisphere having a predetermined radius and a cylindrical continuum having a predetermined length; And
A deflection plate comprising contact electrodes and configured to refract the generated plane wave at an angle using a relationship between the propagation difference of the beams and the distance between the centers of the contact electrodes
Including,
The dielectric lens antenna,
Non-dielectric conductivity

Dielectric lens body;
Non-dielectric conductivity

Dielectric Lens Fill Piece-Above

Above

Greater than; And
Non-dielectric conductivity

In Matching Dielectric Lens Covering-Above

silver

Im-
Including,
Controlled lens antenna device. The method of claim 12,
And the antenna elements are located on a planar surface of the cylindrical continuum. The method of claim 12,
And the dielectric lens antenna is homogeneous or composite. delete Antenna elements in an integrated circuit configured to transmit beams;
A dielectric lens antenna configured to generate a plane wave based within the transmitted beams, wherein the lens of the dielectric lens antenna comprises a hemisphere having a predetermined radius and a cylindrical continuum having a predetermined length; And
A deflection plate comprising contact electrodes and configured to refract the generated plane wave at an angle using a relationship between the propagation difference of the beams and the distance between the centers of the contact electrodes
Including,
The dielectric lens antenna,
Dielectric lens body; And
A dielectric lens fill piece,
The dielectric constant of the dielectric lens body is

And the dielectric lens fill piece has a non-dielectric conductivity

It is a peel piece of the phosphorus hyperboloid,
Controlled lens antenna device. The method of claim 12,
Non-dielectric Conductivities of the Dielectric Lens Antenna

And

The dependency of the following Equation 1,
[Equation 2]

remind

Is an angle between the axes of the hyperboloid, and tg is a tangent function. The method of claim 12,
The deflection plate may include a ceramic plate having a dielectric conductivity that changes according to an applied voltage;
Two matching plates; And
Contact electrodes
Controlled lens antenna device comprising a. The method of claim 12,
The angle of deflection of the deflection plate is determined via arcsin (d / s), where d is the radio wave and S is the distance between the centers of the contact electrodes of the deflection plate. The method of claim 12,
And the deflection plate comprises ferroelectric ceramic plates and corresponding layers.

Images