DE2115704A1 - Antenna with a loop antenna element - Google Patents

Description

antenna
with a loop antenna element

The invention relates to an antenna, in particular for television receivers, with a high gain over a wide frequency range.

TV antennas must have a high directivity to avoid ghosting and to avoid the high gain necessary to pick up weak signals in border areas. They are proportionate for this purpose large antennas, known as Yagi antennas, which contain a dipole element with reflectors and directional elements. However, these antennas are not suitable for television receivers for receiving UHF signals, since the impedance characteristics are different and the mutual impedance characteristics between the antenna elements, the reflector and the directional element change depending on the frequency, so that the spacing of the electrical members of the antenna elements is changed must be in order to receive VHF and UHF signals.

The invention is therefore based on the object of an antenna suitable for television receivers with a high directional effect and to provide high gain that is small in size, low in manufacturing cost, and if desired can be mounted in a television receiver. The antenna according to the invention contains a loop antenna antenna element and a dipole antenna element, the latter being formed together with the loop element by in a circular plate is provided with an opening. There-

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at the outer edges of the plate form the loop antenna element and the remaining segment parts of the plate are the dipole elements. With such an antenna according to the invention, the area of the opening is selected between 1/8 and 7/8 of the plate area. That way you get the optimal impedance for receiving electromagnetic waves over a wide frequency range.

The antenna according to the invention has a constant impedance over a wide frequency range. The antenna points furthermore a sharp directivity. Their dimensions are small. The manufacturing costs are low.

These and other features of the invention are apparent from The following description of some exemplary embodiments illustrated in the drawing emerges. Show it

Fig.l is a front view of an antenna according to the invention;

2A, 2B and 3 Smith diagrams of the antenna according to FIG

Fig. ¹ JA is a front view of a dipole antenna;

4B shows a diagram (admittance as a function of the frequency) for the antenna according to Fig. ^ A;

Fig. 5A is a front view of a loop antenna;

FIG. 5B shows a diagram (admittance as a function of frequency) for the loop antenna according to FIG Pig.5A; .

Fig. 6 is a diagram showing the frequency admittance

Shows characteristic of the antenna according to the invention;

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Pig.7-10 front views of further embodiments the invention;

11 is a perspective view of a in antenna according to the invention housed in a television receiver;

Fig. 12 is a front view of a parabolic antenna element according to the invention;

FIG. 13 shows an end view of the antenna element according to FIG. 12;

Fig.l4 a view of the antenna with the antenna element of FIG. 12 and a dipole antenna element attached in front of it;

Fig.15 is a diagram showing the front-to-back ratio as a function of frequency for the antenna of Fig.I ^ shows;

Fig.l6 is a front view of a further embodiment of the invention;

17 and 18 are perspective views of further embodiments;

Fig. 19 is a diagram showing the frequency-gain characteristic the antennas of Figures 17 and 18 and a Yagi antenna;

Fig. 20 is a diagram for explaining the directivity the antenna according to FIG. 17;

21A, 21B and 21C further exemplary embodiments of the invention Antennas;

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Fig. 22A is a perspective view of a further embodiment ;

FIG. 22B shows a perspective detail of a component of the antenna according to FIG. 22A.

The embodiment shown in Fig.l contains a circular conductive plate 1 with a diameter i ₃ which is approximately equal to 1/3 of the longest wavelength of an electromagnetic signal to be received. In the plate 1 an opening 2 is provided in the form of two sector parts 2a, 2b which are connected to one another at their apices; In this way, the two sector-shaped parts 3a, 3b made of conductive material remain. The edge part, the thickness t of which is small in relation to the diameter of the plate 1, adjoins the window parts 2a, 2b. Feed points 4a, 4b are provided at the vertices of the parts 3a, 3b adjacent to the center 0 of the plate 1. In a practical embodiment, the plate had a diameter I of 250 mm; the angle θ of the sector parts 3a _s 3b was 60 and the thickness 1 was 10 mm. In this exemplary embodiment, the area of the window 2 is equal to 5/8 of the total area of the panel 1. If the total area of the panel is denoted by S before the window is cut open, the area of the window 2 is equal to 5/8 S.

Fig. 2A is a Smith chart with a curve a-b -.- c, -d, for the antenna of Fig. 1, the points corresponding to the frequencies 460 MHz, 500 MHz, 600 MHz and 780 MHz, respectively. The characteristic impedance of the antenna was 200 ohms (corresponding to a reference point 1.0 in the Smith diagram). Curve a to d in FIG. 2A shows that the impedance of the antenna of FIG. 1 remains approximately constant in the frequency range between 460 MHz and 780 MHz. In a second exemplary embodiment of a UHF antenna, the diameter L became equal to 250 mm

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chosen, the strength t equal to 10 now and the angles θ of the sector parts 3a, 3b equal to 15 °; the characteristic impedance was 200 ohms. The curve a.-b ^ -c ^ -d ^ in Pig.2A illustrates the frequency-admittance characteristic of the antenna. In a third embodiment, the diameter and thickness were chosen as in the two first embodiments; however, the angle θ was 30 °. The curve ap-bp-Cp-dp ^veranscnau ü ^cn ^ the frequency-admittance characteristic of this embodiment.

Pig ·. 2B shows a Smith chart for a fourth embodiment with the same diameter and thickness as in the examples above, but with an angle θ of 120 °. The curve a ^ -b ^ -c ^ -d ^ illustrates the Admittance of the antenna as a puncture of the frequency in the area between 460 and 780 MHz. The curve a ^ -d ^ is the characteristic an antenna with the same diameter and the same strength as in the above embodiments, but with an angle 0 of 150 °. The curve ag-dg finally shows the characteristic of an antenna with the above dimensions, but with an angle θ of 180.

The curves of Pig.2A and 2B show that the impedance of an antenna can be seen as a puncture of the frequency in the frequency range between 460 and 780 MHz can be kept essentially constant by adjusting the angle θ of the elements 3a, 3b selects in the range between 30 and 150 °.

Figure 3 illustrates the frequency-admittance characteristics of antennas according to Pig.l, the diameter £ equal to 250 mm, the angle θ of the sector parts 3 equal to 60 °, the characteristic impedance was chosen equal to 200 ohms and the width t of the curved edge parts 5 between 5 mm, 10 mm and 40 mm was varied. The frequency was measured at 460 MHz, 500 MHz, 600 MHz, 8OO MHz and 98Ο MHz, respectively

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the points a, b, c, d and. e in the Smith chart. The curve a ₇ -e_ corresponds to a thickness t equal to 5 mm, the curve ao-βο to a thickness t equal to 10 mm and the curve aq-eq to a thickness of the part 5 of 40 mm. 3 shows that when the thickness t of the curved part 5 is between 5 and 20 mm, the impedance remains essentially constant in the frequency range from 460 to 980 MHz.

From the above experimental results it can be concluded that when the area of the window 2 is between 1/8 and 7/8 of the total area of the conductive plate before removal of the window part is chosen, the antenna is excellent Impedance properties over a wide frequency range owns.

Fig. ¹ IA illustrates a dipole antenna 6 with the segments 3a, 3b of the antenna 1 and 5A a loop antenna 7 having a diameter and a thickness d I. It can be seen that the antenna of Flg.l represents a combination of the dipole of FIG. IA and the loop of FIG. 5A (combined to form a one-piece antenna). Fig.MB shows the frequency-admittance characteristic of the dipole of Fig.4A, which is in resonance at a frequency that is slightly smaller than a wavelength of -ψ-. In FIG. 4B, the susceptance component (susceptance component) is illustrated by the solid line 6G, which is equal to 0 _{at the central frequency f Q;} the conductance component (conductance component) is shown with the dashed line 6B, which has its maximum at the central frequency f _Q.

The loop antenna 7 has the characteristic shown in FIG. 5B; curve 7G shows the susceptance characteristic which _{runs through U at f Q} , while curve 7B illustrates the conductance characteristic.

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The curves of Pig. 6, which represent the characteristics of the antenna of Pig. 1, form a combination of the curves of Pig. ¹ IB and 5B for the antennae of the Pig. ¹ IA and 5A. Thus, for example, the solid curve 86 is obtained for the suseptance characteristic of the antenna of FIG. 1 by combining the curves 6G and 7G for the antennas of FIGS. 1 A and 5A. The conductance characteristic 8b, which is shown in dashed lines in FIG. 6, is obtained by combining the characteristics 6B, 7B of the antennas in FIGS. ^1, JA, 5A. It should be emphasized in particular that the susceptance characteristic 8G has a value approximately zero over a very broad frequency range.

2A, 2B, 3 and 6 show that the antenna according to the invention has an impedance that is above an extreme wide frequency range is constant, which cannot be achieved with conventional antennas. This enables a Impedance matching of the antenna to the receiver over a wide frequency range and prevents losses through a Mismatch between antenna and receiver; this is also a prerequisite for a broadband antenna. the The antenna according to the invention can also be implemented in a very small construction compared to conventional antennas .

FIGS. 7 to 10 illustrate further exemplary embodiments of the invention. According to FIG. 7, a circular plate I ^{1 contains} a window 2 'which consists of two circular window parts 2a ¹ , 2b' which are offset from the center of the plate and are connected to one another through an opening. The parts 3a ¹ , 3b ¹ extend inwards from the outer edge of the disc to the opening and serve as a dipole, while the outer edge 5 'acts as a loop. The antenna can be connected to points 4a ', ¹ Ib'.

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In the modified embodiment shown in Pig.8 the plate 1 contains "a window 2", which consists of two approximately elliptical openings 2a "and 2b", which are arranged symmetrically to the center of the plate and connected to one another through an opening. Connection points 4a ", 4b" are provided near the center of the plate; the dipole parts 3a ", 3b" extend up to these connection points. The loop part is labeled 5 ".

9 shows an approximately square plate 11 with an opening 12, which consists of two approximately triangular) parts 12a, 12b. These triangular window parts 12a, 12b are connected to one another in the region of their apex and form connection points 14a, I ¹ Jb. The triangular parts 13a, 13b of the plate form a dipole, while the outer edge 15 represents the loop part of the antenna.

Fig.10 shows an antenna in the form of an approximately hexagonal Plate 21 with a window 22 shaped in the form of an hourglass, which has an upper part 22a and a has lower part 22b. The connection points 2fta, 24b are near the center of the plate 21; the parts . 23a, 23b form the dipole part of the antenna and the edge 25 the loop part of the antenna.

It was found that the antennas shown in Figs. 7 to 10 have the same characteristics as that Have antenna of Fig.l.

11 illustrates the antenna according to the invention mounted in a television receiver. The antenna of Fig.l can for example in a vapor deposition process or after Type of printed circuit. Example

as the antenna 1 can be formed on an insulating plate on the inside of the wall of the television receiver housing 9 (see Fig. 11) is attached. A connecting line 10 carries the output signal of the antenna from the connection points 4a, 4b to the receiving part of the television receiver to.

FIGS. 12 and 13 illustrate a modified one Embodiment of the invention in which the antenna has a parabolic shape and is used as a reflector will. A parabolically shaped plate 100 has the windows 20a, 20b in a sector shape with the apex angles Θ. The windows 20a, 20b are arranged symmetrically relative to the center of the plate 100. When executing Fig. 12 and 13, the windows 20a, 20b touch in the area of their Do not part; rather, the material of the plate 100 extends from one conductive segment 30a to the other conductive one Segment 30b. Fig. 13 is a side view of the antenna of Fig. 12 and illustrates its height h. The antenna diameter is denoted by L and the thickness of the edge is denoted by t. The letter H denotes the center line of the antenna, which intersects the sector parts 30a, 30b in the middle.

Fig.I J ¹ illustrates the reflector 100 of Figure 12 and 13 mounted opposite a dipole 101 having the connection points 104a, 104b. The reflector of Figures 12 and 13 is labeled A; the dipole antenna 101 has a length I and a diameter w and may for example be made from bar material. The dipole 101 and the reflector A are spaced apart by a distance d, the dipole being in front of the reflector so that it absorbs the radio frequency energy indicated by the arrow RF. The center 0 of the reflector A coincides with the center 0 'of the dipole element 101; the dipole 101 is oriented relative to the reflector as shown.

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- ίο -

The frequency characteristic of the front-to-back ratio of the antenna according to FIG. 14 is shown in FIG. It applies to an antenna with a diameter L of the reflector of 250 mm, a width t of the curved part 50 of 10 mm, a depth h of the reflector of 40 mm, central angles θ of the penster parts 20a, 20b of 120 °, a length i des Dipoles 101 of 200 mm, a diameter w of the dipole of 6 mm, a distance d between dipole element 101 and reflector (see FIG. 14) of 140 mm. Curve 112 in FIG. 15 is the characteristic of an antenna similar to that in FIG. 14 ₉ , however, the reflector element does not contain any windows. When comparing the characteristics 111 and 112, it can be seen that the removal of the windows 20a, 20b brings about a substantial reduction in the front-to-back ratio and accordingly considerably reduces the directivity of an antenna. The curve in FIG. 15 shows the front-to-back ratio of a loop antenna with a reflector of the same configuration. It can thus be seen that the antenna according to the invention according to FIG. 14 represents a significant improvement over known antennas and has a pronounced directivity in a wide frequency range.

The tests with the various illustrated "embodiments showed that very good results are obtained, when the area of the windows in the antenna is between 1/8 and 7/8 of the total area of the conductive plate (before formation the window). At this magnitude of the window area, the front-to-back ratio of the antenna becomes does not deteriorate, but remains good over a wide frequency range.

Fig.lö illustrates an embodiment of the invention, in which, as a modification of the antenna of Fig.l, a coil 14 is connected to points 4a, 4b. The antenna 1 can also be designed in a parabolic shape as shown in FIG

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will. By changing the value of the inductive element IM, an apparent change in the shape of the reflector 1 can be achieved. The coil 14 can thus be used to change the characteristics of the antenna, for example in a manner analogous to the end load of a dipole. If desired, an impedance can also be used in connection with the reflector according to FIG. 1M .

Figure 17 illustrates a composite antenna at eight ·. Elements, including a first parabolic element A according to FIGS. 12 and 13 and a second element B, which is arranged in front of the element and has the configuration shown. The element B forms;, the Emitter and element A the reflector. Directional elements are the dipole antenna elements 15a to 15f, which are as shown are arranged. The embodiment of Fig. 17 results in an antenna with high directivity and high gain.

According to Fig.l8, the element A and the dipoles 15a to 15f are arranged in the same way as in Fig.17; as a spotlight a triangular dipole antenna element 16 is used. This antenna also has a high Gain and a pronounced directional effect.

The antennas of FIGS. 17 and 18 represent significant improvements over conventional Yagi antennas. FIG. 19 illustrates the gain as a function of the frequency. The curve 191 shows the gain as a function on the frequency for a conventional yagi antenna. Curve 181 illustrates the gain-frequency dependency the antenna according to Fig.l8 and the curve 171 the gain-frequency dependency of the antenna according to Fig.17. A comparison of curves 171 and 18l with curve 191 shows the substantial improvement achieved over the Yagi » Antennas.

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Pig.20 is the directional diagram of the antenna of the S ¹ Ig. 18 for an incoming signal of 600 MHz. It can be seen from FIG. 20 that the front-to-back ratio of the antenna consisting of a large number of elements according to FIG. 18 is infinitely large and that the directivity is very good.

FIGS. 21 and 22 illustrate further exemplary embodiments of the invention. These figures show a modified form of the antenna according to FIG. 1 * 1; the dipole and the parabolic elements are used as radiators and as a sector, respectively, and are spaced apart by a distance d. The dipole element 101 is connected to elements 10a which are used for impedance matching and which can be designed as solid conductors of the twin line type. The end of the elements intended for impedance matching which faces away from the dipole 101 is connected to a suitable connection. In order to achieve a good impedance matching, the characteristic impedance Z _Q of the elements 10a used for impedance matching is chosen so that the relationship Z ₀ = J Z. χ Z ^ is ensured, where Z. and Ζ, the impedances of the antenna element 101 and of the feed. The length u of the elements 10a depends on the frequency range to be detected.

FIG. 21B illustrates the dipole element of FIG. 21A in an arrangement with a parabolic reflector 100 according to FIG. 14. The distance between the dipole 101 and the antenna 100 is denoted by d; the length £ of the dipole 101 is chosen as a function of the working frequency. It is difficult to select the optimal length u of the impedance matching elements 10a and the distance d between the antenna elements 100 and 101 and the length t at the same time, since the self-impedances of the antenna elements 100 and 101 and the mutual impedance between them are frequency-dependent. Fig. 21C illustrates the dipole

2 0 8 8 1 4 / in the p

antenna element 101, which is bent back as shown and has an optimal length £. The dipole element 101 is coupled to elements 10a intended for impedance matching and having the optimal length u; it will based on the impedance Z. of the dipole 101 at the connection points, the impedance Z, the lead and the operating frequency range selected. If the ends of the dipole 101 are bent back in the direction of the element 100, so the effective length between the dipole antenna element and the antenna element 100 becomes shorter. Will on the other hand If the dipole is bent so that its ends extend away from the element 100, the length u becomes that for impedance matching serving elements 10a longer. You can thus the length u of the elements 10a and the distance d between the Set the dipole element 101 and the antenna element 100 to the optimal value by bending the ends of the dipole 101 appropriately selects the angle which these ends form with the elements 10a.

Fig. 22 illustrates a practical embodiment of the antenna according to Fig. 21. The end of the element 10a intended for impedance matching which is remote from the dipole 101 is held in the center of the antenna element 100 via an insulator 117 (see FIG. 22B). The end 10b of the element 10a is pivotably mounted on the holder 117, so that a vertical movement of the element 10a relative to the antenna element 100 is possible. A slidable bracket 17 is mounted on the element 10a (see FIG. 22B). By this arrangement, the antenna can be moved up in ⁿ diS Fig. 22A dashed be folded position when the antenna is not used. This is useful for storing or using the antenna. The antenna element 100 is composed of a conductive plate with a window and can be supported on a disk-shaped plate made of molded synthetic resin, by which the necessary mechanical strength is provided. The element 100 is from one to one

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_ 111 _

Mast 20 attached to the base 19 is supported by a support arm 21.

The antenna according to FIG. 22 speaks in a wide range Frequency range on; the distance between the dipole antenna element 101 and the antenna element 100 and the The length of the element 10a intended for impedance matching can be chosen optimally depending on the working frequency range will.

The window in element 100 is symmetrical about the center of the conductive plate, albeit substantially the same results can also be achieved with an asymmetrical window. If the Window it may be necessary to provide an impedance matching element between the antenna and the receiver.

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Claims (1)

Claims 1.1) Antenna with a loop antenna element, a dipole antenna element, the outer ends of which are electrical are connected to the loop antenna element and with an opening between the loop and dipole antenna elements, characterized that the opening has an area of 1/8 to 7/8 of the outer dimensions of the loop antenna element has limited area. 2.) Antenna according to claim 1, characterized in that the outer ends of the dipole antenna element are wider than the inner ends are. J>.) Antenna with a conductive plate part, a window provided therein which is narrower in the central area of the plate part than in the part remote from the center, characterized in that the window has an area between 1/8 and 7/8 that of the outer dimensions of the conductive part has a defined area. 4.) Antenna according to claim 3, characterized in that the conductive plate part is disc-shaped. 5.) Antenna according to claim 3, characterized in that the conductive plate part is polygonal. 6.) Antenna according to claim 3 »characterized in that Connection points are formed on the conductive plate near the narrow part of the window. 2G9824 / 0S3? 7.) Antenna according to claim 1, characterized in that the inner ends of the dipole antenna element are electrical are connected to each other. 8.) Antenna according to claim 3, characterized in that an inductance is connected through the window in the narrower part is. 9.) Antenna with a conductive plate part, a window provided therein, which is symmetrical to the center in such a way is attached that the window has its narrow point in the center, characterized in that the Window has an area between 1/8 and 7/8 of the area enclosed by the conductive plate part. 10.) Antenna according to claim 9, characterized in that adjacent on opposite sides of the window to the center of the plate part connection points are connected to the conductive plate part. 11.) Antenna according to claim 9, characterized in that the window consists of two parts which are connected to one another in the center of the plate part. 12.) Antenna according to claim 9, characterized in that an inductance is provided through the window in the center is. 13.) Antenna with a conductive plate part, at least two provided in the plate and symmetrical to the Center of the plate arranged window openings, furthermore with a mounted in front of the conductive plate part Antenna element, characterized in that the window openings have an area between 1/8 and 7/8 the area enclosed by the conductive plate part. 209824/0532 21Ί570Α 14-) antenna according to claim 13, characterized in that the antenna element is a dipole antenna. 15.) Antenna according to claim 14, characterized in that with the dipole antenna and with the conductive plate part an element serving for impedance matching mechanically connected is. 16.) Antenna according to claim 13, characterized in that the dipole antenna has two arms which are inclined to the conductive Plate part are arranged. 17.) Antenna according to claim 15, characterized in that the element used for impedance matching consists of one solid, conductive twin ladder part. l8.) antenna with a parabolic conductive plate part, an insulator supporting this plate part and two window openings provided in the plate part which are arranged symmetrically to the center of the conductive plate part, 'characterized in that the window openings have an area between 1/8 and 7/8 of the area enclosed by the plate part, that one for impedance matching serving element with one end insulating with the center of the conductive plate part is connected and is formed by a solid twin conductor and that a dipole antenna element on the other The end of the element used for impedance matching is attached. 10.) Antenna according to claim 18, characterized in that the dipole antenna element in such a way with the impedance matching certain element is connected that the dipole element is pivotable relative to the conductive plate part. 2Ö9824 / 053? 20.) Antenna according to claim 18, characterized in that the element serving for impedance matching is pivotable is connected to the conductive plate part so that it can be folded up. 21.) Antenna with a parabolic conductive plate part and two provided in the plate part, symmetrically attached to the center of the plate part window openings, characterized in that the window openings have an area between 1/8 and 7/8 of the area enclosed by the conductive plate part, that W an antenna element is attached in front of the conductive plate part and serves as a radiator, and that an antenna element is arranged between the conductive plate part and the dipole antenna elements and acts as a directional element. 22.) Antenna according to claim 21, characterized in that the radiator by a wide conductive plate part is formed and has two window openings whose area is between 1/8 and 7/8 that of this second conductive plate part enclosed area. 23 ·) Antenna according to claim 21, characterized in that the radiator contains a dipole antenna. 20S824 / OS3?