DE2004865A1 - Ultra-short wave broadband transmission antenna - Google Patents

Description

21) 04-865

- February 3 - 1970

593S-IV / La

■ IliOIiSOIi-CSF, Paris 16 ^e , Boulevard! Iurat 101 (France)

"Ultra lairzwel len- tire it band s endeantenna ^t!

French priority dated February 4, 1939 from French patent application PV 69/239 ¹ I

(His)

The invention relates to an ultra-short wave broadband transmission antenna with at least one radiator unit.

Antennas of this type are used on a large scale, particularly in frequency-modulated radio transmitters and television transmitters. Depending on whether the radiation should take place uniformly in all directions or whether certain directions should be preferred, the radiation diagram of the antenna used should either have omnidirectional characteristics or be more or less directional. Antennas of this type, the radiation properties of which can be changed, generally consist of several radiator units with directional effect, which are electrically independent of one another and whose arrangement and supply are selected depending on the desired radiation diagram, \

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A well-known and very widely used Fon .; is the aoss from dipole fields. installed antenna. It usually consists of an arrangement of four dipole fields that are attached to the top of a mast and are aligned in four mutually perpendicular directions. Every·? The dipole field consists of several individual dipoles that are fed together and are arranged in front of a reflector. If the four fields are fed in phase and with the same power, an essentially circular nori ^ o ^ t?.! Diagram, i.e. an omnidirectional diagram, while a different distribution of the feed power between the four fields leads to the formation of a directional diagram.

Such antennas made of dipole fields are very often used for frequency-modulated or for television transmitters. You own nevertheless, certain disadvantages such as a relatively complicated and delicate structure, for example against mechanical and electrical influences Rime and ice are difficult to protect, namely 3ov: ohl because of the presence of the dipoles themselves as well as \ .errcii the presence of the reflectors.

Another type of antenna, the so-called slot antenna, can be used to radiate ultra-short waves in a broad frequency band. A known embodiment of a slot antenna consists of a vertical cylinder which is provided with one or more vertical slots along its generatrix . The structure of such an antenna is obviously much simpler than that of an antenna with dipole fields; However, the radiation properties are less favorable, especially with regard to the bandwidth and the possibility of achieving diagrams with adjustable directional characteristics * u.

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In another type of slot antenna, the elements in which the radiating slots are arranged and which are used as Fields or are designed as cylinders, arranged in front of reflectors around a support mast. These antennas have the Advantage that the diagram can be influenced thanks to the independent radiator elements; the presence of However, reflectors complicate their construction.

The invention is now based on the object of an ultra-short wave broadband transmission antenna to create with at least one emitter unit with sufficient bandwidth and simple Structure is designed so that its radiation pattern can be influenced. It is further in line with the objective the jj .'- 'invention to train the antenna so that it can be provided with a low-cost anti-icing protection.

This task is at c here voi ^ escV: agenen antenna solved by the fact that the invention ·. ·.; I turn off the powering unit a reflector in the form of a cylindrical conductive surface and a radiator, which consists of two a dihedron forming conductive surfaces is constructed, the edge of which runs parallel to the generatrix of the cylindrical surface and its inner angle facing the reflector is between approximately 90 ° and 100 ° and an angle running along the Xante Slit is provided, the length of which is approximately equal to the mean wavelength of the waves to be emitted and the is fed in the middle of the transmission energy.

The fact that the individual reflectors, which are assigned to the directional fields of dipole antennas, are replaced by a single cylindrical reflector, which at the same time forms part of the bearing dimensions, results in a considerably simpler antenna structure. This also results in a ■

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considerable simplification of the antenna assembly and a shortening of the assembly time.

It is easily possible to influence the input impedance, the bandwidth, etc., the slot width of the invention Antenna to be dimensioned accordingly, with this width over the slot length both constant and variable can be.

Is the antenna attached to or around a mast that does not consist of a conductive cylinder and / or a has a cross-section deviating from the circular shape, it is sufficient to remove the part of the mast on which the dihedron is to be attached, to be provided with a conductive cylindrical surface.

According to a preferred embodiment, there is the inventive Antenna made up of three radiators called slotted diaphragms, each offset from one another by 120 °, around a cylindrical one Reflector-forming mast are arranged around.

By appropriately feeding these three slotted diaphragms, both a round jet diagram and diagrams can be created win with differently pronounced main lobes.

It is particularly advantageous to connect the two flat surfaces forming the dihedron with the associated To connect reflector in such a way that the supports electrically and mechanically on the one hand with the reflector, on the other hand with the surfaces forming the dihedral are connected at points where the stress distribution curve has a node.

The simple structure of the antenna according to the invention enables the slots of the slot diaphragm to be formed with little effort

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to protect panels forming a radome. Influences on the electrical and mechanical properties in particular by ice are avoided.

Of course, as with other antennas consisting of individual elements, the slotted dihedral can be placed around the reflector forming mast can be arranged in several levels to increase the antenna gain in the vertical diagram. Here is It is advantageous that, like each individual radiator, the entire antenna arrangement is mechanically very stable and not very sensitive against influence, for example by icing.

In the drawing, an antenna of the type according to the invention is illustrated schematically in an embodiment shown as an example. Show it:

1 shows a perspective, greatly simplified view of a radiator unit according to the invention, which has a directional antenna forms,

Fig. 2 is a greatly simplified plan view of an arrangement of three radiator units according to FIG Form omnidirectional antenna.

Fig. 1 schematically illustrates the structure of a radiator unit according to the invention. The radiating element consists of two conductive surfaces that form a dihedron 1, its internal angle is at least 90 °. A slot 2 runs along the edge of the dihedron 1 over a length that is approximately equal to the mean wavelength of the waves to be emitted. The slot is in its center with the one to be radiated Energy fed. This feed takes place in a known manner, e.g. via a double line 3, 4, their connection occurred with the main feed line in the usual way is.

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The slit diaphragm thus formed is in front of a conductive cylindrical one Surface 5 arranged, in such a way that the slot of the dihedron runs parallel to the generatrix of the surface. The fastening of the dihedron 1 on the surface 5 is carried out by conductive supports 6 and 7. These supports are attached to the dihedron at points where the wave radiated through the slot has a tension node, e.g. at the two ends of the slot. In a slightly different from the embodiment of FIG. 1 embodiment, the the two conductive surfaces forming the dihedron 1 at the ends of the slot 2 are not mechanically connected to one another and the supports 6 and 7, one end of which is mechanically and electrically connected to the cylindrical surface 5, form the two short circuits at the two ends of the slot 2.

The cylindrical surface 5 can be a cylinder section, as indicated in FIG. 1, or better still a complete one Cylinder. The slotted dihedron according to the invention can consequently be attached directly to a cylindrical mast, which now serves as a support mast for the antenna and as a reflector for the slit dihedron.

The horizontal radiation diagram of such a slot diaphragm is a directional diagram with a main lobe, whose Axis is perpendicular to the plane of the slot. The opening angle of the main lobe is mainly dependent on the inner Angle of the dihedron 1 and of the width 1 of the two surrounding conductive surfaces.

Although the width of the slot 2 does not affect the radiation pattern, it does influence the input impedance of the Diedere. In the case of a slot of constant width, as shown in FIG. 1, by careful choice of this That customization can be achieved in a very wide width

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wide frequency band is retained. However, under certain circumstances and to improve impedance matching use can also be made of a slot, the width of which is not the same everywhere over its length.

The advantages of such a radiator unit are - besides its electrical properties - the simplicity of the construction, so that such a radiator is considerably more economical, than a dipole field and is also much more resistant to external, atmospheric influences. It is sufficient to close the slot 2 with a small radome, as shown in Fig. 2, around the antenna e.g. to protect against hoarfrost.

Another embodiment is obtained if you use the continuous smooth conductive surfaces, which form the dihedron 1, replaced by perforated conductive surfaces. on In this way, the weight of the antenna structure can be reduced, but the structure becomes less insensitive against external influences.

Another advantage of the Schiitzdieders according to the invention is that its horizontal radiation diagram is very well suited for combinations of several dihedra, so that for example an omnidirectional antenna can be obtained.

Fig. 2 shows a schematic plan view of an omnidirectional antenna, in which three slotted diaphragms 9, 10 and 11 are arranged around a cylindrical support mast 8. These three These are distributed symmetrically around the mast 8, which serves as a reflector, the arrangement being chosen so that that .the axes of the main lobes of the horizontal radiation diagrams go through the center of the mast 8 and each enclose an angle of 120 ° with one another;

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the slots are fed in phase in their middle and with the same power. This arrangement results in an antenna with an excellent round beam characteristic in the horizontal radiation diagram.

The diameter of the mast 8 serving as a reflector and ■ the distance between the slots of the three dihedra from the mast influence the horizontal radiation pattern of the antenna. The diameter of the mast at the height of the dihedron can advantageously be approximately two thirds of the mean wavelength of the waves to be emitted, while the distance of the slot each Dieders from the pylon can be chosen to be approximately equal to a third of this wavelength.

The ones used to fasten the three dihedral 9, 10, 11 to the mast Supports 15, 16, 17 in Fig. 2 correspond to the upper supports 6 in Fig. 1. Three other identical supports, which are the supports correspond to Fig. 1, are not shown in Fig. 2; they are attached to the lower part of the dihedral. Im illustrated here For example, the two surfaces forming each dihedron are not connected to each other and the six supports such as 15, 16 and 17 also serve as short circuits at the respective two ends of the slots.

In Fig. 2, small radomes 18, 19 and 20 are also simplified indicated, which form insulating fields and form the slots, for example, against hoarfrost.

The following is an exemplary embodiment of a transmitting antenna for frequency-modulated transmissions, the frequency band of which, band II, is between 87.5 and 100 MHz. In this example, the essential elements of the antenna were advantageously given the following dimensions; ui _ie , on:

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Mast diameter: 2 m

Inner angle of the Schiitzdieder: 100

Length of the slots: 3 m

Width of the slots: 0.3 m

Distance between slot and mast: 1 m

Dimension 1 of the surfaces forming each dihedron: 0.83 m.

The mutual electrical independence of the three slots of an antenna, as shown in Fig. 2, allows the radiation pattern to be changed in a simple manner. It is sufficient for this purpose, the three dihedral either in amplitude or in phase to different services like feed in order to achieve the antenna is a partial directivity and to prefer certain radiation directions.

In certain cases it is also possible to use a directional antenna from a single slotted rod attached to a mast or to form with two slotted dihedral elements, which are advantageously offset from one another by 120 ° horizontally on the mast; this Angle turns out to be the most favorable for a composition or superposition of the radiation patterns of the slotted dihedral according to the invention.

Among the numerous advantages of the slit diaphragm according to the invention the simple mechanical structure must be emphasized, which leads to a much lower price than, for example, the production of dipole fields, as well in addition, it makes assembly much easier, less fragile and consequently easier Maintenance. Nevertheless, the radiation properties are considerably improved.

With regard to the omnidirectional antenna built with three slotted dihedral it can be said that besides the advantages

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mechanical properties of the slotted dihedral adhere
has a horizontal radiation diagram that corresponds to the ideal
Pie chart is close enough to the radiation in all
Directions to ensure. The vertical radiation diagram corresponds essentially to that of an antenna made of dipole fields, which it advantageously replaces. i

Claims;

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Claims (1)

February 3, 1970 THOMSON-CSF 59 3 8-IV / La P at e nt to check Ultra-short wave broadband transmission antenna with at least one radiator unit, characterized in that the radiator unit consists of a reflector in the form of a cylindrical conductive surface (5) and a radiator which is made up of two conductive surfaces forming a dihedron (1), the edge of which is parallel to the Generating the cylindrical surface (5) and whose inner angle facing the reflector is between about 90 and 100 and a slot (2) running along the edge is provided, the length of which is approximately equal to the mean wavelength of the waves to be emitted and that in the Middle is fed by the transmission energy. 2. Antenna according to claim 1, characterized in that the the width of the slot which determines the input impedance (2) is constant. 3. Antenna according to claim 1, characterized in that the Slot (2) is not the same width everywhere. H. Antenna according to claim 2 or 3, characterized in that that it is mounted on a mast and that the part of the hurry where it is mounted is cylindrical and the Forms reflector for the or the Schlitzdieder said radiator. 5. Antenna according to claim H, characterized in that it consists of three Schlitzdiedern O ₅ 10, 11), which by each 0098 32/1729 -42 - 120 ° offset from one another, are arranged around a mast forming the cylindrical reflector (8). '6. Antenna according to claim 5, characterized in that the three slotted diaphragms (9, 10, 11) in phase and with the same power to achieve an omnidirectional pattern be fed. 7. Antenna according to claim 5, characterized in that the three slotted diaphragms (9, 10, 11) are out of phase and with different Power are fed in such a way that the Main lobe of the horizontal diagram of each dihedron and its Direction are adjustable. 8. Antenna according to one of claims 1 to 7, characterized in that that the two flat surfaces forming the dihedron (1) via conductive supports (6, 7) with the associated Reflector are connected, the conductive supports electrically and mechanically on the one hand with the reflector (5), on the other hand, they are connected to the surfaces forming the dihedron at points where the stress distribution curve unites Knot on v / eist. 9. Antenna according to one of claims 1 to 8, characterized in that the slots of the slot dihedral with a radome (18, 19, 20) are protected. 10. Antenna according to one of the preceding claims, characterized in that the slot dihedral around the reflector forming haste are arranged in several levels to increase the antenna gain in the vertical diagram. BATH ORIGINAL 00 f> 832/1729 Blank page