RADAR ANTENNA AND SUITABLE METHOD FOR INFLUENCING THE RADIATION CHARACTERISTICS OF A RADAR ANTENNA

Abstract

A radar antenna includes parasitic elements for influencing the radiation characteristics of the radar antenna, the radiation characteristics of the radar antenna being dependent upon the spatial position of the parasitic elements relative to the radar antenna and phase positions (φ1, φ2, φ3) of energies radiated off the radar antenna and the parasitic elements. The radar antenna is designed using microstrip technology.

Claims

1. A radar antenna, comprising: parasitic elements for influencing the radiation characteristics of the radar antenna, the radiation characteristics of the radar antenna being dependent upon the spatial position of the parasitic elements relative to the radar antenna and phase positions of energies radiated off the radar antenna and the parasitic elements, wherein the radar antenna is designed using microstrip technology.

2. The radar antenna of claim 1, wherein the arrangement of the parasitic elements relative to the radar antenna results in broadening of the radiation characteristics of the radar antenna in an azimuthal direction.

3. The radar antenna of claim 1, wherein the arrangement of the parasitic elements relative to the radar antenna results in focussing focusing of the radiation characteristics of the radar antenna in an azimuthal direction.

4. The radar antenna of claim 1, wherein the radar antenna comprises one or more antenna lines designed using microstrip line technology.

5. The radar antenna of claim 1, wherein the parasitic elements comprise one or more antenna lines designed using microstrip line technology.

6. The radar antenna of claim 1, wherein by mutual coupling to one another and/or by mutual coupling with the radar antenna to be influenced, the parasitic elements change the radiation characteristics of the latter by broadening or focusing the radiation characteristics in an azimuthal direction.

7. The radar antenna of claim 1, wherein the parasitic elements are arranged on one or both sides parallel to a longitudinal axis of the radar antenna to be influenced.

8. The radar antenna of claim 1, wherein the parasitic elements are in the form of antennas or antenna lines having a defined termination at a base point of the antenna.

9. The radar antenna of claim 1, wherein the radar antenna and the parasitic elements are covered with a radome.

10. The radar antenna of claim 1, wherein the use of the radar antenna with parasitic elements operates in a frequency range between 1 MHz and 200 GHz.

11. The radar antenna of claim 1, wherein the use of the radar antenna with parasitic elements operates in a frequency range between 70 and 80 GHz.

12. The radar antenna of claim 1, wherein the radar antenna is used as a transmitter, receiver, or combined transceiver antenna.

13. The radar antenna of claim 1, wherein the radar antenna is part of a radar system for determining the position and/or speed of objects.

14. A radar system comprising: the radar antenna with parasitic elements for influencing the radiation characteristics of the radar antenna according to claim 1.

15. A method for influencing the radiation characteristics of a radar antenna using parasitic elements, the method comprising: a) propagating energy from a signal source to a transmitting antenna; b) radiating the energy from the transmitting antenna into a space, the radiated energy having a phase position φ1, wherein some of the energy radiated from the transmitting antenna striking the parasitic elements; c) reflecting some of the energy striking the parasitic elements from the parasitic elements and radiating some of the energy reflected from the parasitic elements into the space, the radiated energy reflected from the parasitic elements having a phase position φ2; d) receiving, by the parasitic elements, some of the energy striking the parasitic elements; and e) reflecting some of the energy from the parasitic elements to the transmitting antenna; wherein the radiation characteristics of the transmitting antenna are influenced by the energy radiated from the parasitic elements, and the energy radiated from the transmitting antenna overlaid with the energy radiated from the parasitic elements.

16. The radar antenna of claim 1, wherein the parasitic elements comprise a short-circuited line end, a termination with an absorber, or a power adjustment.

Description

[0014] An advantageous configuration of the present invention is shown with reference to the following drawings:

[0015] FIG. 1 shows a radar antenna system according to the application using microstrip line technology.

[0016] FIG. 2 shows a radar antenna system according to the application with a number of antenna lines using microstrip line technology.

[0017] FIG. 3 shows the radiation characteristics according to the radar antenna system according to the application.

[0018] FIG. 4 shows energy distribution within the radar antenna system according to the application.

[0019] In FIG. 1, 1 represents the antenna line to be influenced using microstrip technology which preferably has parasitic elements 2 arranged in parallel and which are also shown as antenna lines using microstrip technology.

[0020] Another advantageous configuration consists in using a number of antenna lines to be influenced using microstrip line technology according to FIG. 2 and which are influenced by parasitic elements 2, the parasitic elements 2 being arranged doubly in parallel as antenna lines using microstrip technology. At this point it should be stressed that depending on the number of parasitic elements arranged in parallel, the radiation characteristics can be influenced accordingly for the radar antenna system according to the application.

[0021] In FIG. 3 the radar antenna system according to the application of FIG. 1 is shown, illustrating to what extent the radiation characteristics of the influenced radar antenna 1 can bring about improved illumination, in particular in the peripheral zone region. In FIG. 3 the radiation characteristics corresponding to the azimuth angle Θ are also reproduced, and this reflects broadened radiation characteristics with a corresponding antenna gain 3.

[0022] In FIG. 4 the qualitative description of the influence of the radiation characteristics by the mutual coupling between a transmitting antenna and two parasitic elements according to the illustration of FIG. 1 is reproduced. Energy from the signal source 0 is propagated to the radar antenna acting as the transmitting antenna. Energy is then radiated from the transmitting antenna into the space. Some of the energy strikes the parasitic elements. Some of the energy is reflected by the parasitic elements and is radiated into the space. The energy radiated off has a phase position φ1. The parasitic elements receive energy which is radiated from the transmitting antenna to the parasitic antennas according to 13. With 14 the process is described during which the energy is reflected by the parasitic elements 2 and is radiated from the radar antenna into the space. The energy has the phase position φ2. 15 designates the energy which is received by the parasitic elements. The energy that is reflected by the parasitic elements 2 to the transmitting antenna 1 is designated as 16. Thus, the radiation characteristics of the transmitting antenna 1 are influenced by the energy of the parasitic elements that is radiated off. Overlaying of the radiated off energy of the transmitting antenna 1 with the radiated off energy of the parasitic elements 2 takes place. Whether the radiation characteristics are broadened or focussed is dependent upon the spatial positioning of the respective transmitting antennas and parasitic antennas and the corresponding phase position φ1, φ2 etc.

[0023] In this way in particular a radar antenna system is provided which can broaden the radiation characteristics depending on the requirements and in particular can be used advantageously when using microstrip line technologies.