DE3529914A1 - Microwave aerial - Google Patents

Abstract

The microwave aerial consists of an annular conductor loop (1) whose circumference is approximately one wavelength and whose conductor has a greater width. For discontinuity-free matching to a coaxial supply line (2) which is connected to the base-point supply point and to free space, the conductor loop is constructed in the region of the supply point such that a smooth transition is produced by means of a gradual, approximately exponential increase in the distance between the loop inner edges (4, 5). A microwave aerial which is constructed according to the invention, especially using printed-circuit technology, can be used, for example, in active transmitting/receiving modules of an electronically phase-controlled antenna array. <IMAGE>

Description

The invention relates to a microwave radiator in the form of a simple ring-shaped conductor loop, the extent of which is the size of a wavelength and the at a dining point that forms the base of the heater for both Sides of a break from the two conductors one Feed line is fed.

Micro especially suitable for mass production Wave emitters should be constructed so that they are wide bandy (15 to 20%) with regard to their base point Impedance and their radiation pattern that they work reproducibly manufactured in cheap series technology can be and that they can be easily coaxial feed system can be connected.

These demands are largely through a footbridge Horn blaster type meets, as it from DE-OS 33 34 844 is known. In principle, one must be bumpy and discontinuous smooth transition from the feed system to the free space be created for the wave. The problem with that known spotlights with the help of etch printed on both sides circuit board suitably designed printed circuit board structure solved. The main direction of electrical Field gradually from that of one sided one Opposite strip line in the ground those transferred to an inclined dipole would correspond. A disadvantage of this arrangement  is, however, that the electric field on the radiation side contains a remaining cross component, whereby the There is a risk of radiation in cross polarization. In addition, this known microwave radiator a large overall length is required.

In a special print "Antenna Selection Guide" from the magazine "The Electronic Engineer", 1971, different types of radiators are compared with their characteristic properties. From the multitude of the types presented in this special edition, the "vertical all-wave loop" (ring antenna) appears to be suitable for mass production from the base resistance as well as from the radiation diagram and thus also particularly for use in a planar, electronically phase-controlled antenna. The scope of this loop antenna is the size of a wavelength. In the book by "JP Kraus" Antennas "on page 169 for a radiation resistance of approx. 140 Ohm ( Z =), ( Z 1 = characteristic impedance of the coaxial line (= 50 Ohm), Z 2 = characteristic impedance of the air (= 377 Ohm )) also stated that the circumference of the conductor loop corresponds approximately to the wavelength.This dimensioning specification includes that an "all-wave loop" consisting of a thin conductor, for example of thin wire, should be designed optimally only for one frequency is.

The object of the invention is one for one Mass production and especially for use as Radiator element in an electronically phase controlled Group antenna suitable microwave radiators create the reali with a relatively short overall length on the one hand with regard to its base point impedance and its radiation pattern is broadband and for  others almost no cross-polarization components in the radiation of the desired linear polarization having.

According to the invention, which is based on microwaves spotlight of the type mentioned at the beginning, this is Task solved in that the conductor loop forming conductors an inner circumference, that of the smallest occurring wavelength corresponds, and an outer Scope of the largest occurring wavelength corresponds, and that for bumpless adjustment one connected as feed line to the feed point Coaxial line, the conductor loop is designed so that itself - starting from the on both sides of the Interruption opposite conductor loop ends - the distance between the opposite Inner edges of the conductor gradually, at least expanded almost exponentially. For the bumpless Adaptation to both the coaxial line and the Free space is thus ensured by the fact that the Coaxial line emerging electromagnetic field Does not have to change structure abruptly, as with a given a simple circular loop of known type would.

The distance widening is advantageously carried out finally by changing the width of the loop conductor made on that side of the interruption which is the inner conductor of the feeding coaxial line connected.

With a view to mass production, e.g. B. for a electronically phase controlled group antenna is the Manufacture of the emitter as a printed circuit board particularly useful. The conductor loop is in this Case as a printed circuit on an insulating material  existing support plate applied. The material of this The carrier plate can be Teflon, for example.

When implementing the microwave radiator after Invention is in the form of a printed circuit However, it should be noted that the one-sided Metalli sation of the substrate part of the electrical Field in and on the conductor loop partly through the Carrier plate material, partly through the air. The so The resulting field asymmetry is with a carrier material with high dielectric constant in an expedient manner compensate for that a cover plate that from same material as the carrier plate and has the same thickness as on the printed Circuit provided surface of the carrier plate arranged is.

The conductor loop microwave emitter after the Invention can expediently as a transmission or Receive radiator of an active module in a planar, electronically phase-controlled antenna can be used. Each module then carries one at its head end in accordance with the Invention trained microwave radiator by the inner circuit parts of the module is supplied. The Signals can be routed coaxially through the module housing will.

Essential points with the microwave radiator after the Invention are thus the gradual opening of themselves opposite inner edges of the conductor loop in the Area of the dining area, the easy transition from one unbalanced to a largely symmetrical waves leadership and ease of manufacture, which is good  reproducible radiator properties results.

The changed wave guide on the according to the invention Executed feeding point of the conductor loop can too a slight secondary radiation, which is then a ge squinting the main radiation direction in the Conductor loop level results. This more possible wise resulting disadvantage can be easily compensate for the fact that with a complete Radiator field (array) corresponding to the front surface is inclined in opposite directions.

If you manufacture the emitter using etching technology, you can it also as an integral part of an RF circuit using stripline technology - possibly with a suitable one Adaptation network - use.

The invention is illustrated below in four Illustrated embodiments illustrated.

Show it

Fig. 1 of a micro-processing technique in a top view the embodiment wave radiator according to the invention in printed scarf,

Fig. 2 shows the microwave radiator shown in FIG. 1 in a sectional side view II, III-II, III,

Fig. 3, also in a sectional side view II, III-II, III the cover plate is provided with a microwave radiator shown in FIG. 1

Fig. 4 is a plan view of the schematic arrangement of a plurality of microwave radiators according to Fig. 1, which serve as radiator elements of an electronically phase-controlled group antenna.

In Fig. 1 in a plan view, an embodiment is shown of a microwave radiator according to the invention in printed circuit technology. This radiator consists of a simple ring-shaped conductor loop 1 , the circumference of which is the size of a wavelength and which is fed at a feed point forming the radiator base on both sides of an interruption 3 from the inner conductor 6 and outer conductor 10 of a coaxial line 2 . The conductor loop 1 forming the conductor is attached as a metallization on a support plate 7 , which is made of insulating material, for. B. made of Teflon. The conductor forming the conductor loop 1 has a greater width, so that the radiator can work properly in a frequency band, for example 20% wide. Such a broadband effect with regard to the base point impedance and the radiation diagram can be achieved per se by jointly using different loop lengths in one conductor track. For bumpless adaptation to the coaxial line 2 , the conductor loop 1 is designed such that - starting from the opposite ends of the conductor 3 on both sides of the interruption - the distance between the two opposite inner edges 4 and 5 of the conductor 1 gradually, at least approximately exponentially expanded. The distance expansion takes place finally by a change in width of the loop conductor 1 on that side of the interruption 3 to which the inner conductor 6 of the feeding coaxial line 2 is connected.

The inner conductor 6 is thus connected to a tip of the conductor loop 1 . Along the rectilinear edge 8 of the rectangular support plate 7 , via which the coaxial feed is fed, a metallization strip 9 , which acts as a mass, is printed, which is connected approximately in the middle to the outer conductor 10 of the coaxial feed line 2 and in which this is not connected to the inner conductor 6 of the coaxial feed line 2 connected end 11 of the conductor loop 1 while maintaining its width opens approximately vertically.

In a sectional side view II, III-II, III in Fig. 2, the embodiment shown in Fig. 1 of a microwave radiator according to the invention is shown. In Fig. 2 it can be seen that a part 16 of the electric field in and on the conductor loop 1 through the material of the carrier plate 7 and another part 15 leads through the air through the one-sided metallization of the carrier plate 7 made of insulating material. This creates a certain field asymmetry.

This field asymmetry according to FIG. 3 is compensated for by a cover plate 12 , which consists of the same material as the carrier plate 7 and has the same thickness as the carrier plate 7 . This cover plate 12 is arranged on the surface of the carrier plate 7 provided with the printed conductor loop 1 . This results in a symmetrical electric field, the field lines of which are designated 16 and lead through the carrier and cover plates 7 and 12 , respectively.

Referring to FIGS. 1 to 3 carried out microwave radiators can be used as transmit and receiving antenna of an active module in a planar phased array used (electro nic phased array antenna).

An example of such a group antenna is shown in plan view in FIG. 4. Each module carries at its head end a microwave radiator according to FIGS. 1 to 3, which is supplied by the internal circuit parts of the module. The modules are arranged in large numbers in a triangular grid and can be replaced individually. In FIG. 4, in a cutout 17 of the phase-controlled antenna 14 delimited by the border 18 , the microwave emitters forming the antenna elements of the antenna according to the invention are designated by 13 . The cost-effective production method in the form of etched conductor tracks and the low overall height of the radiating element meet the requirements existing with a phase-controlled group antenna. The signals can be routed coaxially through the module housing.

Claims (11)

1. microwave radiator in the form of a simple ring-shaped conductor loop, the circumference of which is the size of a wavelength and which is fed to the feeder forming the feeder on both sides of an interruption by the two conductors of a feeder line, characterized in that the conductor loop ( 1 ) forming conductor has an inner circumference, which corresponds to the smallest occurring wavelength, and an outer circumference, which corresponds to the largest occurring wavelength, and that for the smooth adaptation to a coaxial line ( 2 ) connected as a feed line at the feed point, the conductor loop is formed in this way is that - starting from the conductor loop ends facing each other on both sides of the interruption ( 3 ) - the distance between the opposing inner edges ( 4 , 5 ) of the conductor gradually and at least approximately exponentially expands. 2. Microwave emitter according to claim 1, characterized in that the extension of the stand is made by suitable shaping of the loop itself and by changing the width of the loop conductor on that side of the interruption ( 3 ) on which the inner conductor ( 6 ) of the feeding coaxial line ( 2 ) connected. 3. Microwave emitter according to claim 1 or 2, characterized in that the conductor loop ( 1 ) is applied as a printed circuit on a carrier plate ( 7 ) consisting of insulating material. 4. Microwave emitter according to claim 3, characterized in that the material of the carrier plate ( 7 ) is Teflon. 5. Microwave emitter according to one of claims 3 or 4, characterized in that the edge ( 8 ) of the carrier plate ( 7 ), via which the coaxial feed is carried out, is straightforward, that a printed metallization strip ( 9 ) is provided along this edge, the Approximately in the middle with the outer conductor ( 10 ) of the coaxial feed line ( 2 ) is connected and into which the end ( 11 ) of the conductor loop ( 1 ), which is not connected to the inner conductor ( 6 ) of the coaxial feed line, opens approximately vertically. 6. Microwave emitter according to one of claims 3 to 5, characterized in that a cover plate ( 12 ) is arranged on the surface of the carrier plate ( 7 ) provided with the printed circuit, which consists of the same material as the carrier plate and has the same thickness as that Carrier plate. 7. Microwave emitter according to one of the preceding claims, characterized by the use as a transmitting and / or receiving radiator ( 13 ) of an active radiator and phase shifter module in a preferably planar, electronically phased antenna ( 14 ). 8. microwave emitter according to claim 7, characterized by the arrangement on the head end of the module and by feeding from the inside Circuit parts of the module forth, the signals in Coaxial lines and / or stripline technology are guided through the module housing. 9. Microwave emitter according to claim 7 or 8, characterized in that the modules are arranged in large numbers individually replaceable in a triangular grid ( Fig. 4). 10. Microwave emitter according to one of claims 3 to 9, characterized in that a due to the special wave guidance in the area of Resulting angular deviation (squint angle) the antenna main beam direction in the conductor loops level is compensated for by the fact that the front of the entire radiator field (array) in opposite directions Direction is inclined. 11. Microwave emitter according to one of the claims 3 to 10, characterized in that when it is created in printed circuit technology Part of a stripline technology trained RF circuit, possibly with a suitable adaptation network is provided.