EP1800369A1

EP1800369A1 - Radar antenna assembly

Info

Publication number: EP1800369A1
Application number: EP05799646A
Authority: EP
Inventors: Lutz KÜHNE; Markus Wintermantel
Original assignee: ADC Automotive Distance Control Systems GmbH
Current assignee: ADC Automotive Distance Control Systems GmbH
Priority date: 2004-10-11
Filing date: 2005-10-07
Publication date: 2007-06-27
Anticipated expiration: 2025-10-07
Also published as: EP1800369B1; DE502005004839D1; KR20070072573A; ATE402501T1; DE102004049626A1; JP2008516567A; WO2006039896A1; KR101237334B1; US8847835B2; DE112005001523A5; JP5013267B2; US20120200465A1

Abstract

A radar antenna arrangement, in particular for motor vehicles, is presented, having of a longitudinal waveguide, into which electromagnetic waves are coupled in such a manner that they expand in the longitudinal direction (X) of the waveguide, and an interference structure (12) with a plurality of metallic sections, whereby the interference structure in proximity to the waveguide, at a distance from the waveguide in a first transverse direction (Y) to the waveguide, is arranged at least approximately parallel to the longitudinal direction (X) of the waveguide, so that the interference structure effects an adjusted radiation of the radar waves. The waveguide comprises in the longitudinal direction two metallic surfaces (31, 41) and between these, a dielectric medium (32, 42), whereby the surfaces (31, 41) run in a second transverse direction (Z), which stands both vertically to the first transverse direction (Y) and to the longitudinal direction (X) of the waveguide. Preferably, the interference structure (12) is designed as a rotatable drum with metallic sections which are changed on the circumference and a reflector arrangement is provided for bundling and polarizing the waves.

Description

Radar antenna array

The present invention relates to a radar antenna arrangement according to the preamble of claim 1, in particular radar antennas for radar sensors for motor vehicles, which enable a pivoting of the antenna characteristic.

State of the art

From US 5572228 and US 621186 a leaky-wave antenna arrangement is known, which is realized as a mechanically pivoting antenna, by rotating a surface-structured drum in the immediate vicinity of a dielectric waveguide. The surface texturing of the drum is in US 557228 carried out by individual metal strips whose distance changes during rotation of the drum in the region of the dielectric waveguide. This causes a rotation angle-dependent power extraction via a so-called leaky wave from the dielectric waveguide. The decoupled power is distributed in space in each case in the form of a radiation writable by a directed antenna characteristic, which is referred to below as a radiation lobe whose intensity maximum is thus dependent on the respective rotation angle of the drum. The polarization of the radiated wave is oriented parallel to the metal strip present on the drum.

An alternative embodiment of the drum is described in US 621186. There, the surface structure is carried out by individual rows of means such as elevations and depressions of the drum with suitably chosen dimensions with respect to length and width. By appropriate design as well as a targeted influencing the polarization plane of the radiated lobe is possible. However, the design of the individual rows of means on the drum results in discrete pivoting of the lobe, whereas the aforementioned embodiment also permits continuous pivoting.

The basic principle of the dielectric waveguide which is disturbed by a variable, structured surface in order to emit a leaky wave has already been mentioned in WO 87/01243. In addition to the above-mentioned restrictions with respect to polarization and in the second case of discrete tilting, the dielectric waveguide included in the arrangement is problematic for the practical implementation of the antenna, which at least over certain lengths free floating in the immediate vicinity of the drum with great precision (even under environmental influences such temperature and vibration, etc.) must be arranged.

Furthermore, in the plane perpendicular to the plane of oscillation of the radiation lobe (sectional plane through drum and dielectric conductor), the geometry of the dielectric conductor results in a very broad characteristic of the radiation cone, which must be bundled by an additional reflector and / or a microwave lens. This results in a very expansive, in particular for automotive applications unacceptable, size of the entire antenna array.

The present invention has for its object to provide a radar antenna assembly, which is suitable for use in a radar sensor for automotive applications.

The radar antenna assembly is preferably intended to enable continuous or discrete pivoting of one or more lobes, each in a variety of directions, in a simple and cost-effective manner, thus suitable for use in a low-cost and high-performance radar system, in particular a radar system for automotive applications.

This object is solved by features of claim 1. Advantageous developments are given in the dependent claims and the description.

According to the invention, an alternative type of waveguide is used, which is arranged in the vicinity of the interfering structure, for example the above-mentioned surface-structured drum. This waveguide has spaced metallic surfaces, between which a dielectric medium is arranged. As a dielectric medium in addition to solid dielectrics and gas, eg. Air, into consideration. The electromagnetic wave is coupled in between the metallic surfaces in the longitudinal direction. The metallic surfaces extend longitudinally, are open in the first transverse direction to the interfering structure and the opposite side and spaced from each other in the second transverse direction, wherein the second transverse direction is perpendicular to both the first transverse direction and the longitudinal direction of the waveguide. This waveguide can advantageously be integrated in a metallic and therefore highly robust base, which makes the waveguide particularly reproducible in manufacture and resistant to environmental influences. The additional use of dielectrics is possible. The radar antenna arrangement is preferably supplemented by a suitable reflector system for beam focusing in the plane orthogonal to the plane of oscillation of the radiation lobe, which enables the development of the smallest possible and very simple construction of the entire antenna arrangement. In this case, advantageously a folded reflector system consisting of polarizer and reflector array is used, as was presented with conventional exciters (eg waveguides or patch antennas) in DE 19848722. By this arrangement, the polarization plane of the radiation lobe is rotated, which is not possible with the overall arrangement described in US 5572228 without additional measures. In addition, reflector systems with a novel metallization structure are conceivable, as can be seen by the non-prepublished PCT / DE 2004/001925. Deviating from a usual gain-optimized metallization structure, the metallization structure is detuned by omitting or additionally adding defined metallizations and thus influencing the beam shape.

drawings

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description. Show it:

1 shows a longitudinal section through the arrangement consisting of a drum and an exemplary waveguide,

2 shows a cross section through the arrangement consisting of a drum and an exemplary waveguide,

3 shows an exemplary embodiment of the waveguide,

4 shows a cross section of a waveguide with an attached horn for pre-focusing the radiated power,

Fig. 5 shows a cross section of an overall arrangement with folded reflector system

Fig. 6 shows an alternative cross section of an overall arrangement with folded reflector system.

Description of the embodiments

Fig. 1 shows an exemplary waveguide 11 in the immediate vicinity of a drum 12 having a textured surface. In this waveguide 11, a power in the high frequency region is fed, which propagates along the waveguide 11 in the form of an electromagnetic wave. The surface structuring of the drum 12 engages - A -

into the electromagnetic fields around the waveguide and decouples power from the array, which is thus radiated in the form of a radiation lobe in the room. The direction Θ of the intensity maximum of the radiation lobe results, for example, in the case of a periodic arrangement of structuring on the drum 12 due to the context

where A _{0 is} the free space wavelength, λ _{g is} the wavelength on the waveguide and p is the pitch of the patterns on the drum. Due to the reciprocity theorem, the arrangement operates in the same way in the case of reception.

In the prior art, the waveguide 11 is designed as a dielectric waveguide with a circular or rectangular cross-section surrounded by air. According to the invention, however, the waveguide 11 advantageously, as shown in Fig. 3 outlined as a composite structure of a metal frame 31 and a dielectric 32 realized.

This waveguide resembles in its cross-section the H-guide given in the literature - in contrast, however, with very limited in extent metal walls - operated in the present arrangement with a kind of parallel plate mode with electric field lines in relation to Fig. 3 horizontal polarization becomes. He is referred to below as a slot conductor. The metallic surfaces 31 extend in the X direction and are spaced apart in the Z direction. The surfaces 31 need not necessarily be flat surfaces, but may, for example, be designed as rods. However, the shape of a flat surface proves to be advantageous for fixing a solid dielectric therebetween. The waveguide is open in the Y direction to the interference structure and to the opposite side, in which the decoupling takes place

The dielectric medium 32 has a decisive influence on the wavelength and the cross-sectional dimensions of the slot conductor, which can also be operated overmoded for the present antenna function.

As a cross section of a solid dielectric 32 different shapes are conceivable, for the practical implementation are advantageous rectangular, almost rectangular and hexagonal versions. The strength of the field coupling with the surface of the drum 12 is in addition to the distance 23 shown in Fig. 2 between the waveguide 21 and drum 12 by choice of the material of the dielectric 32, the cross-sectional dimensions of the dielectric 32 and the dimensions 33, 34, 35 and 36 adjustable within certain limits. In an extreme case, the slot conductor in FIG. 3 can also be operated with air as the dielectric medium 32. An advantageous development of the slot conductor is shown in FIG. 4. The slot conductor consisting of metallic enclosure 41 and dielectric 42, here with an exemplary cross-sectional geometry, is additionally provided with a funnel construction 43, which realizes pre-focusing of the radiation lobe in the plane orthogonal to the plane of oscillation (cutting plane through drum and slot conductor).

In Fig. 5 is a cross-section of an overall antenna arrangement with additional reflector system consisting of a sub-reflector and a main reflector for Strahlbündeiung in the plane of rotation of the radiation lobe (sectional plane through drum and slot conductor) orthogonal plane. The radiation lobe coupled out of the waveguide 51 through the surface of the drum 12 in the immediate vicinity strikes a polarizer subreflector 53, which is constructed of a dielectric material with applied metallic grid 54 or metallic stripes. The power is completely reflected on it and thrown onto a designated as a twist reflector main reflector 55, which is advantageously designed as a Reflect array. This forms or bundles by a location-dependent reflection behavior, the radiation lobe in addition to the plane of rotation of the original lobe orthogonal plane and simultaneously causes a polarization rotation of the lobe by 90 °, so that the power can then pass through the polarizer unhindered. The essential advantage of this arrangement over the prior art is that it results in a comparatively very compact design and a small overall space requirement. The Reflect array consists z. B. from a dielectric plate, which on the side facing the incident waves a plurality of metallization and on the side facing away from the incident waves has a continuous metallization. The dielectric plates of the reflector can be formed not only flat but also curved. A particularly advantageous embodiment results when, in addition to the o. G. Polarization rotation and shaping in the plane perpendicular to the pivoting plane of the original beam lobe further additional shaping and / or pivoting of the radiation lobe in the pivoting plane of the original beam is made. This is possible by suitably designing the metallization structures on the dielectric plate.

In Fig. 6, an alternative cross-section of an overall antenna arrangement is given. The funnel-shaped slot conductor 61 near the drum 12 in turn energizes a reflector antenna having a subreflector 63 as a polarizer and a main reflector 65 designed as a twist reflector to provide the above-described desired additional shaping of the beam in the plane of rotation of the original beam Radiation lobe orthogonal plane and the pivot plane of the original beam to achieve and to rotate the polarization plane by 90 °.

An advantageous development of an overall antenna arrangement such. As shown in Fig. 5 or Fig. 6 consists in the placement of two or more waveguides in the vicinity of the drum, which also extend at least approximately parallel to the structured surface. Thus, two or more mutually independent, simultaneously usable and, if necessary, of the form different radiation lobes are realized with a total antenna arrangement.

A further advantageous embodiment of an overall antenna arrangement such. B. in Fig. 5 or Fig. 6 is shown, the main reflector 55 and 65 rotatably support, so that an additional mechanical pivoting of the radiation lobe by tilting the reflector z. B. in the directions 58 or 68 is possible.

In a specific embodiment, the main reflector 55 or 65 and / or the subreflector 53 or 63 have a curved surface.

The exemplary described total antenna arrangements allow the implementation of a radar system with one or more continuously or discretely tilted in space beams. In this case, the beam width and the realized angular range for the beam tilting can be flexibly adjusted within wide limits by suitable design of the surface used for power extraction. When using a drum surface, it is z. B. possible to realize a plurality of angular ranges as pivoting ranges of the radiation lobes, each with different shapes of the radiation lobes.

Claims

claims

1) Radar antenna arrangement, in particular for motor vehicles, consisting of a) at least one elongated waveguide in which electromagnetic waves are coupled in such a way that they propagate in the longitudinal direction (X) of the waveguide, b) an interference structure (12) having a plurality of metallic Sections, wherein the interference structure in the vicinity of the waveguide, spaced from the waveguide in a first transverse direction (Y) to the waveguide, at least approximately parallel to the Längs¬ direction (X) of the waveguide is arranged so that the interference structure causes a directed radiation of radar waves, c) characterized in that the waveguide has two metallic surfaces (31, 41) and between them a dielectric medium (32, 42), the surfaces (31, 41) extending in the longitudinal direction and spaced apart in a second transverse direction (Z) are, wherein the second transverse direction both perpendicular to the first transverse direction (Y) and the Longitudinal (X) of the waveguide stands.

2.) Radar antenna arrangement according to claim 1, characterized in that the waveguide is a one of metallic plates (31, 41) or rods edged dielectric material (32,42) with a rectangular or hexagonal cross-section.

3.) Radar antenna arrangement according to claim 1, characterized in that the waveguide of two spaced at a certain distance metallic plates (31, 41) or rods is formed, between which is air or other gas as a dielectric medium (32,42).

4.) Radar antenna arrangement according to one of the preceding claims, characterized in that on which of the interfering structure (12) facing away from the waveguide is an opening from the waveguide ago metallic funnel device (43) is provided.

5.) Radar antenna arrangement according to one of the preceding claims, characterized in that means are provided for changing the interference structure (12) by changing the effective metallic sections or their distances from one another.

6.) Radar antenna arrangement according to claim 5, characterized in that the interference structure (12) is designed with a plurality of metallic sections on a drum with a surface structure, such as elevations and / or depressions, which may be continuously and / or discretely different over the circumferential angle and the variation of the interfering structure (12) is realized by a rotation of the drum.

7.) Radar antenna arrangement according to one of claims 1 to 6, characterized in that it serves as a pathogen of a reflector antenna (53,55,63,65) or a lens antenna.

8.) Radar antenna arrangement according to one of claims 1 to 6, characterized in that it serves as the exciter of a reflector antenna for polarized waves, which consists of a permeable for waves of a desired polarization subreflector (53,63) and a main reflector (55,65) for bundled Reflection of the waves with a rotated in a desired direction polarization consists.

9.) Radar antenna arrangement according to claim 7 or 8, characterized in that the reflector or main reflector (55,65) has a dielectric plate, on the side facing the incident waves a plurality of Metallisierungεstrukturen (56,66) and on the incident waves opposite side has a continuous metallization.

10.) Radar antenna arrangement according to claim 8 or 9, characterized in that the sub-reflector (53,63) is a dielectric plate with a metallization in the form of a polarization grating (54,64).

11.) Radaraπtennenanordnung according to one of claims 7 to 10, characterized in that one or more reflectors (53,55,63,65) are rotatably mounted and so about one or more axes (58,68) are tilted.

12.) Radar antenna arrangement according to one of the preceding claims, characterized in that a plurality of waveguides are arranged in the vicinity of the interference structure, which also extend at least approximately parallel to the interference structure.

13) Radar antenna arrangement according to one of the preceding claims, characterized in that by varying the interference structure, a pivoting of the originating from one or / more waveguide beams to cover a plurality of angular ranges or angular sectors in space is possible.

14.) Motor vehicle with a radar antenna arrangement according to one of claims 1 to 13 for detecting objects in the vicinity of the motor vehicle.