The present application claims priority to and the benefit of German patent application no. 10 2009 055 344.4, which was filed in Germany on Dec. 29, 2009, the disclosure of which is incorporated herein by reference.
The present invention relates to an antenna.
Radar systems use antennas to radiate radar beams. Radar systems are known which scan a visual range using a bundled radar beam. This requires an antenna that radiates in only one narrowly defined spatial direction. In addition, this spatial direction of the radiation must be modifiable so that the visual range can be scanned sequentially. Antennas which are suitable for such a task are also referred to as scanners.
Furthermore, antennas are known for which the radiation direction is a function of the frequency of the radiated radar beam. Such antennas are referred to as frequency scanners and are discussed in WO 95/20169 and DE 10 2007 056 910.8, for example. However, currently known frequency-scanning antennas are complex and expensive in the production and offer only a suboptimal directional characteristic or beam bundling.
Therefore, it is an object of the exemplary embodiments and/or exemplary methods of the present invention to provide an improved antenna. According to the exemplary embodiments and/or exemplary methods of the present invention, this objective is achieved by an antenna having the features described herein. Refinements are also described and specified herein.
An antenna according to the present invention has an antenna body equipped with a plurality of first antenna elements, which are disposed along a first straight line. A hollow conductor, which runs between the first antenna elements, is disposed inside the antenna body, the first antenna elements being implemented as openings that run between the hollow conductor and a surface of the antenna body. Furthermore, the antenna is designed to radiate a signal in a spatial direction that is a function of a frequency of the signal. The antenna body has an electrically insulating material which is coated with a conductive material. The antenna body is advantageously able to be produced from an electrically insulating material in a more cost-effective manner than an antenna body made of metal.
The insulating material may be polyetherimide or polybutylene terepthalate. These plastic materials have the advantage of being cost-effective, easy to process, and mechanically robust.
The antenna body may be produced by an injection molding process. A production using an injection molding process is advantageously easier and more cost-effective than milling the antenna body from a block of material.
According to one alternative embodiment, the insulating material is glass. Glass, too, advantageously constitutes a cost-effective and easily processable material that has suitable mechanical properties.
The antenna body is then expediently produced by an embossing method. Embossing methods likewise offer the advantage of allowing a cost-effective and simple production.
The electrically conductive material may be applied by a physical vapor-phase deposition, or with the aid of a galvanic coating method. These coating methods advantageously allow the deposition of a very thin conductive material layer.
A medium that is transparent to radar radiation may be provided inside the hollow conductor. This has the advantage that the conductive material is able to be protected from corrosion.
The hollow conductor may have at least one compensation structure, which is designed to compensate for any interference at the hollow conductor as a result of reflections at the first antenna elements. This advantageously makes it possible to improve the radiation characteristic of the antenna.
At least two of the first antenna elements expediently differ from each other such that they differ in the amount of their radiation output. This advantageously makes it possible to optimize the antenna configuration, which allows an especially advantageous radiation characteristic to be obtained.
In an especially particular manner, the output radiated by the first antenna elements interferes in such a manner that a side lobe attenuation of the radiated output amounts to more than 25 dB in the distant field.
The first antenna elements expediently include an outer antenna element and a central antenna element, the opening forming the outer antenna element having a first diameter, and the opening forming the second antenna element having a second diameter. The first and the second diameters are of different size. The antenna configurations may then advantageously be adjusted via the size of the holes.
In an especially advantageous manner, the first antenna elements include a center first antenna element; the output radiated by a first antenna element is approximately proportional to the square of the cosine of the distance, scaled to π/2, of this first antenna element from the center first antenna element. Tests and calculations advantageously have shown that the use of such antenna configurations makes it possible to achieve an especially advantageous radiation characteristic of the antenna.
In one further development, the antenna has a lens in the form of a cylinder segment. A longitudinal axis of the lens is oriented in parallel with the first straight line. In addition, the lens has a dielectric material. This advantageously makes it possible to focus the beam radiated by the antenna in a direction that runs perpendicular to the swiveling direction of the antenna. This increases the antenna gain.
The lens expediently includes polyetherimide. This material has advantageously been shown to be especially suitable.
In one further development, the antenna has a plurality of second antenna elements, which are disposed outside of the first straight line. The second antenna elements are implemented as patch elements, and at least two of the second antenna elements are connected to each other by a microstrip. The second antenna elements are then advantageously able to be used for detecting a reflected radar signal and thereby improve the resolution of the antenna in a direction that runs perpendicular to the swiveling direction of the antenna. The second antenna elements may also be used for emitting a radar signal.
The second antenna elements may be disposed in one row, which is oriented parallel to the first straight line. The second antenna elements in the row are connected to each other via a microstrip. In an advantageous manner, this system is particularly suitable for detecting the reflected signal, but it may also be used for emitting a radar signal.
In an additional further development, the antenna includes a second antenna body, which has a plurality of third antenna elements, which are disposed along a second straight line. The second straight line is oriented parallel to the first straight line. Furthermore, a second hollow conductor is disposed in the second antenna body, which runs between the third antenna elements. In addition, the third antenna elements are formed as openings running between the second hollow conductor and a surface of the second antenna body. In an advantageous manner, the second antenna body may then be used either for detecting a reflected radar signal, which improves the resolution of the antenna in a direction perpendicular to the swiveling direction of the antenna, or the signals radiated by the first and second antenna bodies may interfere in such a way that improved focusing results perpendicular to the swiveling direction of the antenna.
In one still further development of the antenna, at least one antenna column is provided with a plurality of fifth antenna elements, the antenna column being oriented perpendicular to the first straight line, and the antenna column being coupled to a first antenna element via a coupling structure. In an advantageous manner, the antenna column then brings about focusing of the signals emitted by the antenna, in a direction that is perpendicular to the swiveling direction of the antenna. This improves the radiation characteristic of the antenna.
According to one specific embodiment, the antenna column is implemented as microstrip antenna, the fifth antenna elements being developed as patch elements. The antenna column is then advantageously able to be produced in a simple and cost-effective manner.
A substrate is expediently provided between the antenna body and the antenna column. The substrate advantageously provides an electrical insulation of the antenna column from the antenna body.
According to one alternative specific embodiment, the antenna column is designed as hollow conductor, the fifth antenna elements being implemented as openings in this hollow conductor. In an advantageous manner, such an antenna column designed as hollow conductor likewise brings about focusing of the signal radiated by the antenna, in a direction perpendicular to the swiveling direction of the antenna.
In the following, the exemplary embodiments and/or exemplary methods of the present invention are explained in greater detail with reference to the attached drawing. Matching reference numerals have been used for elements that are the same or act the same.
The joinable surfaces of upper part 110 and lower part 120 each have a meander-type, groove-shaped depression. If upper part 110 and lower part 120 are joined, then the groove-type depressions supplement each other and form a hollow conductor 200 running in the interior of antenna body 105. Hollow conductor 200 extends between an input 210 disposed at an edge of antenna body 105, and an output 220 disposed on the same edge of antenna body 105. Via input 210 and output 220, a high-frequency electromagnetic signal is able to be coupled into and out of hollow conductor 200. The signal may have a frequency of 77 GHz, for example. To swivel the radar beam emitted by antenna 100, the frequency may be varied by an amount of 2 GHz, for instance.
Upper part 110 of antenna body 105 has a plurality of first antenna elements 300, which are situated along a straight line. First antenna elements 300 are developed as openings that run between an outer surface of antenna body 105 and hollow conductor 200 in the interior of antenna body 105. The straight line, along which first antenna elements 300 are disposed, extends parallel to the extension direction of meander-type hollow conductor 200. Each turn of meander-type hollow conductor 200 has an opening forming an antenna element 300. Each antenna element 300 is disposed in the center between two successive turns of hollow conductor 200. However, it is also possible to place antenna elements 300 at other positions of hollow conductor 200, such as in the proximity of, or directly at, the turns of the meander-type extension of hollow conductor 200. For example, 24 or 48 or a different number of antenna elements 300 may be provided. The direct distance between two adjacent antenna elements 300 is selected as a function of the frequency of the signal to be radiated into hollow conductor 200 and may correspond to one half of the wavelength of the signal, for instance. Because of the meander form of hollow conductor 200, the length of hollow conductor 200 between two adjacent antenna elements 300 is greater and, for example, may correspond to approximately 5.5 times the wavelength of the signal.
Antenna body 105 is made from an electrically insulating material, which is coated with a conductive material. The electrically insulating material may be a plastic material, for example, which may be polyetherimide or polybutylene terephthalate. In this case, antenna body 105 may be produced by an injection molding process, for example. As an alternative, antenna body 105 may also be made from glass. In this case, antenna body 105 may be produced by an embossing method, for example. Antenna body 105 may also be made of some other insulating material. A coating of a conductive material is applied on top of the insulating material of antenna body 105. This is necessary so that hollow conductor 200 is suitable for transmitting an electromagnetic wave. The conductive coating may consist of different layer combinations and materials. A coating with gold or aluminum at a thickness of only a few micrometers has shown to be especially suitable. The coating may be applied with the aid of a physical vapor phase deposition, for instance, or with the aid of a galvanic coating method.
In addition, in order to protect the conductive coating from corrosion, hollow conductor 200 may be filled with a medium that is transparent to radar radiation. Suitable for this purpose are low-reaction gases, Teflon, various foams or also a vacuum, for instance. Either only hollow conductor 200 is filled with the medium, for which purpose antenna elements 300, input 210, and output 220 must be sealed by a medium that is transparent to radar radiation or, as an alternative, also entire antenna body 105 may be situated in the desired medium.
The size of the holes forming first antenna elements 300 specifies the output radiated by first antenna elements 300. The distribution of the outputs radiated by the different first antenna elements 300 is referred to as antenna configuration. The development of the antenna configuration has a decisive influence on the directional characteristic of antenna 100. Given a constant configuration, when all first antenna elements 300 radiate approximately the same output, a directional characteristic results that has only a slight side lobe attenuation. An improved antenna configuration, however, makes it possible to improve the side lobe attenuation as well. The directional characteristic of antenna 100 in the distant field results from a Fourier transformation of the antenna configuration. Based on the desired distant field of antenna 100, a suitable antenna configuration is thus able to be calculated. An antenna configuration in which the radiated output of each first antenna element 300 is approximately proportional to the square of the cosine of the distance, scaled to Π/2, of the particular first antenna element 300 to central antenna element 340 has shown to be especially advantageous. The scaled distance of outer antenna element 330 from central antenna element 340 corresponds to a value of π/2. The output radiated by outer antenna element 330 is proportional to the square of the cosine of π/2, that is to say, equal to zero. Correspondingly, antenna elements 300 disposed between outer antenna element 330 and central antenna element 340 have a scaled distance from central antenna element 340 that is smaller than π/2. Outermost antenna elements 330, which radiate an output of zero, may of course also be omitted. However, other antenna configurations are possible as well. Overall, a side lobe attenuation of the radiated output of more than 25 dB is achievable in the distant field of antenna 100.
The exact diameters of the openings forming first antenna elements 300 result from the desired antenna configuration and a correction, which takes into account that the high-frequency electromagnetic signal is transmitted to hollow conductor 200 on one side through input 210. As a consequence, antenna elements 300 more remote from input 210 must have a larger diameter than antenna elements 300 situated in close proximity to input 210.
As explained, the side lobe attenuation of the signal radiated by the antenna is thus able to be optimized by a suitable antenna configuration of first antenna elements 300.
In addition, each antenna column 3150 through 3153 has a coupling web 3200, which likewise is implemented as microstrip and is connected to the microstrip connecting fifth antenna elements 3300. Coupling web 3200 of each antenna column 3150, 3151, 3152, 3153 is disposed above a first antenna element 300 of antenna 3300 and forms a first coupling structure 3700 jointly with this antenna element 300. Via first coupling structure 3700, the output radiated by the individual first antenna element 300 is coupled into antenna column 3150, 3151, 3152, 3153 coupled above respective first antenna element 300. Since antenna columns 3150, 3151, 3152, 3153 are oriented perpendicular to the first straight line, antenna columns 3150, 3151, 3152, 3153 cause focusing of the signal radiated by antenna 3100, perpendicular to the swivel plane of antenna 3100. Coupling structures 3700, as shown in
Antennas 3100, 4100, 5100 of
Antenna 2100 may be used in different ways. The individual antenna bodies 105, 2105, 2106 may either be supplied by a shared high-frequency source, so that individual antenna elements 105, 2105, 2106 radiate in synchrony with each other. In this case, the partial radiation emitted by the individual antenna bodies 105, 2105, 2106 may interfere with each other, so that focusing of the radar beam emitted by antenna 2100 in the y-z plane results. The function of antenna 2100 then corresponds to the function of antennas 3100, 4100, 5100 of
A second possibility for using antenna 1200 is to use only first antenna body 105 for emitting radar radiation, and to detect the reflected radar signal with the aid of second antenna body 2105 and third antenna body 2106. Antenna 2100 then achieves an angular resolution perpendicular to the swiveling direction of antenna 2100. This corresponds to the function of antenna 1100 of
The antennas of the previously described specific embodiments use a hollow conductor 200, which has openings that form first antenna elements 300. However, instead of a hollow conductor, it is also possible to use a microstrip.
The List of reference numerals is as follows:
Number | Date | Country | Kind |
---|---|---|---|
10 2009 055 344 | Dec 2009 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
3197774 | Goldbohm | Jul 1965 | A |
3795915 | Yoshida | Mar 1974 | A |
4742355 | Wolfson et al. | May 1988 | A |
4912474 | Paturel et al. | Mar 1990 | A |
5661493 | Uher et al. | Aug 1997 | A |
6452550 | Channabasappa et al. | Sep 2002 | B1 |
20040080463 | Jeong | Apr 2004 | A1 |
20040174315 | Miyata | Sep 2004 | A1 |
Number | Date | Country |
---|---|---|
102004053419 | May 2006 | DE |
10 2007 056 910 | May 2009 | DE |
0 825 671 | Feb 1998 | EP |
1 199 772 | Apr 2002 | EP |
2 211 420 | Jul 2010 | EP |
2463711 | Mar 2010 | GB |
9520169 | Jul 1995 | WO |
Entry |
---|
Coetzee et al. (“A meandering waveguide planar slot array” 1999 Asia Pacific Microwave Conference; vol. 3, p. 917-919 Nov. 30, 1999). |
Number | Date | Country | |
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20120026053 A1 | Feb 2012 | US |