DE3840451C2 - Lens antenna - Google Patents

Description

The invention relates to a lens antenna according to Ober Concept of claim 1. A lens antenna of this type is already known from DE-OS 21 40 527.

Common lens antennas are either rotationally symmetrical orders and then have directional characteristics with the same or approximately the same club widths in all cutting planes on, or it is cylindrical lenses, the lens only bundles the beams in one plane, while the Beam shaping in the second, orthogonal plane with which Dining facility can happen.

To use a lens antenna with a polar pattern with strong different lobe widths in two orthogonal sections In addition to the cylindrical lens arrangement, it can also create planes one dimensioned according to the known regulations Lens with different lens contours in the two Section planes are used (see e.g. R.C. Johnson, H. Jasik: "Antenna Engineering Handbook", 2nd Edition (Mc Graw- Hill, New York, 1984) chap. 16, page 4).

However, this leads to an elliptical aperture, which is from Primary spotlight is to be illuminated. Then as the primary emitter for example a pyramid horn with very different ones Side lengths are used. The disadvantage of this Spotlights the non-identical phase centers in H-plane and E- Plane and the set polarization plane that matches the plane matches the smallest or the largest club width.  

The Lin known from the aforementioned DE-OS 21 40 527 is characterized in that to achieve the desired spatial radiation pattern one from the sphere dielectric lens as a stationary radiator and at least one pathogen is provided, the pathogen, at for example, a horn, on the surface of the lens be moves or its movement is simulated. The lens can be designed as a cylindrical lens or as a spherical layer lens. The cylindrical lens can have a contour that tapers downwards exhibit. Also described are cylindrical lenses with themselves dielectrics that change continuously or discontinuously in both main axes, which may also taper downwards in their contours. A Similar lens antenna is known from DE-OS 28 49 438.

A dielectric lens is known from US Pat. No. 2,547,416, which is circular and irradiated by a horn radiator Has aperture and in the case of different lens cones structures in the two orthogonal cutting planes of the lens Correction is made in the E or H level.

Other dielectric lenses irradiated by a horn with circular or cylindrical apertures are known from U.S. Patent 4,318,103 and U.S. Patent 3,576,577 and Arti kel by A. D. Olver et al: "Improved radiation characteristics of conical horns with plastics-foam lenses "; in: IEE Proc., Vol. 130, Pt. H, No. 3, April 1983, pages 197 to 202, the Article by L.J. Du et al: "Microwave Lens Design for a Conical Horn Antenna "; in: Microwave Journal, Sept. 1976, pages 49 to 52, and the article by P.J.B Clarricoats et al: "Radiation Pattern of a Lens-Corrected Conical Scalar Horn "; in: Love, A. W. (Editor): "Electromagnetic Horn Antennas", IEEE Press, 1976, pages 300 to 301.

The invention has for its object a lens antenna of the type mentioned in such a way that under Maintaining the directional characteristic with very different cone widths in two orthogonal cutting planes free, independent adjustability of the level of the linear Po larization within the directional characteristic is made possible.

The inventive solution to this problem is in the patent saying 1 described. The other claims contain advantage strong training and further education as well as preferred applications of Invention.

In the following, the invention will be explained in more detail with reference to the figures explained. Show it:

Fig. 1 shows the basic embodiment of the modern fiction, lens antenna, and that its aperture (Fig. 1a) and two mutually orthogonal longitudinal sections (Fig. 1b and 1c)

Fig. 2 shows an advantageous constructive embodiment of the lens of the lens antenna according to the invention shown in FIG. 1 for a particular antenna.

As is shown in the basic design of the lens antenna according to the invention in FIG. 1, a feed antenna is a rotationally symmetrical and therefore inexpensive to produce horn antenna 3 , which also generates a rotationally symmetrical directional diagram (for example in the "Antenna Engineering Handbook" cited above, 15, pp. 19-23 described two-mode horns according to Potter). This is arranged with its phase center in the focal point of a dielectric lens 4 with a circular aperture and irradiates the latter. The lens contour 1 is chosen in the xz plane according to the known writings before, that a spherical wave originating from the focus horn emitter 3 is transferred from the lens 4 into a wave with plane phase fronts.

In the second yz plane orthogonal thereto, the lens contour 2 is designed in such a way that the spherical wave of the food horn 3 emanating from the focal point continues to have non-plane phase fronts after passing through the lens 4 . A possible lens contour shape 2 is here, for example, one with a constant radius of curvature R in the entire lens area. However, other lens contours are also possible that meet this condition. In the xz-section plane, in which the wave has 4 phase fronts after passing through the lens, the lobe width will be the smallest and essentially determined by the lens diameter and the directional characteristic of the feed horn radiator 3 . In the yz plane orthogonal to this, the lobe width can be set in a wide range by selecting the radius of curvature R of the lens contour 2 .

The position of the x'z plane of the linear polarization is only determined by the feed horn 3 and can assume any angle 3 by axially rotating the feed system 3 against the lens 4 , without thereby influencing the shape of the antennas directional characteristic.

Fig. 2 shows an advantageous constructive embodiment of the lens ( 4 in Fig. 1) of the lens antenna according to the invention for frequencies of the microwave, in particular millimeter wave range, namely for frequencies f = 30 GHz ... 100 GHz, in particular for f = 60 GHz ... 70 GHz, preferably for f = 61 GHz. The antenna is shown in a top view ( FIG. 2c), in a longitudinal section ( FIG. 2a) and cross section ( FIG. 2b) and in an overall perspective view ( FIG. 2d).

The lens preferably consists of a dielectric material with a relative dielectric constant ε _r <1 (e.g. plexiglass). However, a material with a relative permittivity constant µ _r <1 can also be used.

The lens surface can be adjusted if necessary structures are provided as they are the prior art correspond.

In addition to the advantage that the above. Requirements regarding the directional characteristic and the independently selectable Polarization plane of the radiation field are met, is a further advantage of the invention, the inexpensive To call production, in which, for. B. the food horn heater as a turned part and the lens as an injection molded part made of plexiglass or the like is produced.

A preferred application of the lenses according to the invention Antenna is used in radar sensors especially for Traffic monitoring and control systems.

It is understood that the invention with expert Can be trained and advanced or to the under different applications can be adapted without this should be explained in more detail here.

So z. B. possible to arrange the primary radiator, ie the feed horn radiator rotatable about the main beam direction (z-axis in Fig. 1), so that the polarization plane (x'z in Fig. 1) can be rotated by any angle ϕ in a convenient manner can.

It is also conceivable to adjust the food for adjustment purposes Hornblower can be moved along the main beam direction to arrange.  

It is also possible to put the lens itself around the main Beam direction of the antenna rotatable or along the main to arrange the beam direction.

Finally, it is conceivable to have several such lenses behind arrange each other with a common main beam direction.

Claims (7)

1. Lens antenna, with a linearly polarized feed horn radiator and a lens permeable to electromagnetic radiation from the electrical material, which lens is curved on the side facing the feed horn radiator in the direction of the feed horn and aligned in two mutually orthogonal and parallel to the main beam direction of the antenna Section planes have different lens contours and which feed horn radiator is arranged with its phase strum in the focal point of the lens and this radiates be, the lens contour in the first of the two mutually orthogonal section planes is selected so that a spherical wave emanating from the focal point of the lens after passing through the lens leads into a wave with flat phase fronts and the lens contour in the orthogonal second sectional plane is selected such that the spherical wave originating from the focal point of the lens is less strongly bound in this sectional plane lt, as in the first sectional plane and therefore after the lens has passed through, continues to have non-plane phase fronts, characterized in that

• 1. that the food horn radiator ( 3 ) is formed rotationally symmetrical and generates a rotationally symmetrical directional diagram;
• 2. that the lens ( 4 ) has a circular aperture and the food horn radiator ( 3 ) irradiates it;
• 3. that the food horn radiator ( 3 ) about the main beam direction (z) of the antenna rotatable and / or along this direction (z) is arranged, and / or
• 4. that the lens ( 4 ) is rotatable about the main beam direction (z) of the antenna and / or along this direction (z) slidably arranged.

2. Lens antenna according to claim 1, characterized in that the feed horn ( 3 ) is a two-mode horn. 3. Lens antenna according to one of the preceding claims, characterized in that the lens contour ( 2 ) in the second cutting plane has a constant radius of curvature (R) in the entire lens area. 4. Lens antenna according to one of the preceding claims, characterized in that the dielectric material of the lens ( 4 ) has a relative dielectric constant ε _r <1 and / or a relative permittivity constant µ _r <1. 5. Lens antenna according to one of the preceding claims, characterized in that the surface of the lens ( 4 ) is provided with fitting structures. 6. Lens antenna according to one of the preceding claims, characterized in that the lens ( 4 ) as an injection molded part is preferably made of plexiglass. 7. Lens antenna according to one of the preceding claims, ge characterized by the use in radar sensors in particular for traffic monitoring and control systems.