DE4327917A1 - Magnetic antenna - Google Patents

Abstract

A magnetic antenna having an antenna conductor in the form of a ring whose circumferential length is preferably less than half a wavelength. The antenna conductor (1) is split at two mutually diametrically opposite points in order to form two radiation sources, and a capacitor (C1, C2), which electrically connects the adjacent ends of the two ring halves (1a, 1b) to one another, is inserted into each of the two separation points (T1, T2), the two ring halves (1a, 1b) which form the radiation sources each being smaller than a quarter of a wavelength and the two capacitors being trimmable and one of the two separation points (T1) being used as an energy supply point or energy output point. <IMAGE>

Description

The invention relates to a magnetic antenna, with an antenna conductor in the form of a ring, the circumferential length of which is preferably less than λ / 2.

Such antennas are also known as loop antennas. This out pressure clearly shows that it is a loop in which a high-frequency current flows. The current is compared to a half-wave dipole much stronger in the loop. This has resulted in the current being strong, "magne to attribute "effects, and therefore the term" magnetic Antenna ". Here, as in the following, the term" magnetic antenna "is used only used because it belongs to German technical language; actually han it is an electromagnetic antenna, of which the loop antenna or loop antenna is one of many. Such loop, loop or "magne "Antennas prefer the magnetic one for the radiation in the near field Component of the electromagnetic field, what they are damping Room walls, concrete ceilings and the like are relatively insensitive power.

Magnetic antennas are a. known from radio direction finding technology. They consist in generally from an electrically conductive, in particular metallic ring, for. B. made of copper or aluminum with a circumferential length that is preferably less than is λ / 4. The ring is separated at one point, and is in the area of the separation point a variable capacitance, in particular a variable capacitor, for frequency mood inserted. At the diametrically opposite point of separation Page is made e.g. B. a low-impedance (50 Ω) feed with adjustment either inductively via a loop which is considerably smaller in diameter or via a so-called gamma adjustment. Such a gamma adjustment works that the shield of an unbalanced feed line (coax cable) at the grounding point the loop (current maximum, diametrical to the tuning capacitor) connected and the inner conductor to the right or left thereof at a predetermined distance (Adaptation 50 Ω) is galvanically connected (see red trunk, antennas book, 11th edition 1989, p. 375, picture 20.4b) - D1 -.

High impedance can e.g. B. via a serial capacitor at the frequency-determining Variable capacitor can be fed. Such a magnetic antenna is e.g. B. be known from EP 0 200 078 B1, Fig. 2, or from (D1), see Figure 20.3b on p. 375.  

If such a known magnetic antenna is tuned to resonance, the current maximum is usually at the point of the loop which is diametrically opposite the rotary capacitor. The current behaves almost like a direct current, which would flow with the same strength at all points of the loop, or in other words: the current in the loop is quasi-stationary. This is the cause of the small concentration of the radiation from a magnetic antenna. The radiation diagram corresponds to a double circle with very little deviation, cf. Fig. 2 of the accompanying drawing. This diagram is generally known as the diagram of the magnetic elementary radiator. The gain compared to a half wave dipole is g = -0.39 dB. This negative gain means a loss of around half a dB, which is essentially caused by the design.

The invention has for its object a magnetic antenna of the beginning to create defined type, which compared to the known magneti described or loop antenna a sharper directivity and a higher Ge winn has.

The invention relates to a magnetic antenna with an antenna conductor in the form of a ring, the circumferential length of which is preferably less than λ / 2, in which the object is achieved according to the invention in that the antenna conductor to form two radiation sources at two diametrically opposite one another Places is separated and in each of the two separation points a capacitance is inserted which electrically connects the adjacent ends of the two ring halves, the two ring halves forming the radiation sources ( 1 a, 1 b) each being smaller than λ / 4 and the both capacities can be coordinated and one of the two separation points serves as an energy feed-in or output coupling point. In relation to the received or transmitted electromagnetic waves of wavelength λ, it is true that each half of the ring is preferably <λ / 4 and both are dimensioned together, ie the ring is preferably <λ / 2.

Advantageous developments of the subject matter of the invention are in claims 2 to 6 specified.

The advantages achievable with the invention can be seen above all in the following: By the size of one or (in the drawing or in practice) above lying capacity, which is ideally as large as the frequency determining  Capacity at the bottom feed point, the circular magnetic An tenne divided into two magnetic antennas. This gives two radiations swell to the effect. A double source is always better than a single radiation source. In practice, the upper capacity is e.g. B. an adjustable trimmer. On in this way, the current maxima at the equator of the circular loop, where they act as opposite phase current elements with 180 ° Phase difference for a strong longitudinal radiation in the plane of the circular loop care and at the same time reduce the superfluous steep radiation. In the This is because the radiations of the current phases in opposite phases rise vertically largely on. The same applies to the transverse radiation, which is also reduced. The new antenna according to the invention already has one without further measures Bandwidth of 1 MHz in the 2m band. So that they ver for the entire 2 m band is reversible, it is conveniently at your dining place with a trade usual FM variable capacitor of 2 × 10 pF.

Further features and advantages of the invention as well as its mode of operation will be described explained in more detail below with reference to the drawing, in which an embodiment the invention is shown. The drawing shows:

Fig. 1 is a schematic representation of magnetic or grinding-An antenna (magnetic loop) according to the invention

Fig. 2 shows the radiation diagram of a previously known loop antenna,

Fig. 3 is a radiation diagram for a magnetic antenna according to the inven tion.

Fig. 4 shows a variant of a detail of the magnetic antenna of FIG. 1.

Referring to FIG. 1, the circular loop antenna 1 of a magnetic MA, consisting, from a. B. 2 mm thick wire made of copper or aluminum, a first separation point T1 at the base and a second separation point T2 at the apex. The two separation points T1, T2 thus sit at two diametrically opposite points of the loop or ring 1 , so that two semicircles or ring halves 1 a, 1 b are formed. A capacitance C1 or C2, which electrically connects the adjacent ends of the two ring halves 1 a, 1 b, is inserted into the two separation points T1, T2. As the voting arrow shows, the two capacities C1, C2 can be tuned. One of the two separation points (T1) serves as an energy feed-in point if the magnetic antenna MA shown serves as a transmitting antenna, or as an energy decoupling point if the antenna MA serves as a receiving antenna. Both capacitances C1, C2 preferably have the same value. Therefore, in the middle of each of the two ring halves 1 a, 1 b there is a current maximum I _max . In addition, there is a phase shift of 180 ° between the two maxima due to the additional capacitor C2. If the circumferential length of the antenna MA is less than λ / 2, then the distance between the two maxima I _{max is} less than λ / 2π. The voltage maxima U _max , on the other hand, are in the area of the two separation points T1 and T2. Each of the two ring halves 1 a, 1 b thus has a current / voltage distribution like a shortened λ / 2 dipole, in which the feed (decoupling) point in the range of the current maximum I _max would have to be thought of.

Each of the two capacitances C1, C2 has - compared to a magnetic loading antenna with approximately the same dimensions (but with a circumference <λ / 4) and with a ring that is simply cut open and with a single one into the separation point inserted tuning capacity - about twice the capacity value as that Tuning capacity of the reference antenna.

In the area of the energy coupling-in and coupling-out point, the capacitance C1 preferably consists of at least two partial capacitances C11, C12 connected in series to one another, with two partial capacitances, as shown, the center tap 2 lying between their one pads a, b as the one pole P1 and the other coating c ei ner of the two partial capacitances C11 as the other pole P2 is used to connect a feed or decoupling cable 3 . The center tap 2 is preferably connected to ground M, ie P1 = M. The feed or decoupling cable 3 is connected to the pole P1, P2 via a small tuning capacitance C3 of z. B. 2 pF connected. The cable 3 has a characteristic impedance of approximately 50 Ω. The capacitance C1 can be formed by a commercially available VHF rotating capacitor of 2 × 10 pF. The phase shifter capacitor C2 at the apex of loop 1 must have the same capacitance as possible, ie 5 pF. I (ϕ) denotes the crescent-shaped current distribution on the two ring halves 1 a, 1 b, each of which has its current maximum I _max over half the circumferential length.

By changing the tunable capacitance C3, the ripple on the cable 3 can be brought to the desired minimum.

According to FIG. 4 , in addition to the partial capacitances C11, C12, the detail of the coupling / decoupling point in the area of the capacitance C1 can be provided with two further tunable capacitances C13 and C14, which are each connected in series with C11 and C12 and for setting the center position serve the current maxima I _max on the ring halves 1 a, 1 b.

Fig. 2 shows, as I said, the radiation diagram of a conventional loop antenna with only one separation point and consequently only one radiation source. The radiation diagram corresponds to a double circle with very little deviation. Such a diagram is generally known as a diagram of the magnetic elementary radiator (cf. Hille-Krischke, "The Antenna Encyclopedia") and corresponds to the diagram of the electrical elementary radiator, in which the E and H planes have been exchanged.

In Fig. 3, the gain of the magnetic antenna according to the invention is documented. One recognizes the relatively slim radiation lobes 4 , 5 , which are the same size forwards and backwards. The front-to-back ratio is 1 or logarithmic scale 0 dB. The already small in the case of small antenna loops is reduced even further, so that the new antenna is also well-suited for miniature bearings.

In Fig. 2 as well as in Fig. 3, the loop plane shows from left to right. The gain of the antenna MA according to the invention is documented in FIG. 3 in the slim radiation lobes 4 , 5 , which are the same size in the front and in the rear, as already mentioned. Comparable to the radiation pattern is shown in Fig. 3 with that generated by two point radiation sources having the same amplitude and the same phase, but are spaced apart by λ / 2 (corresponding to 180 °), wherein the I Field vectors are interchanged with the H field vectors. Compare Kraus, Antennas, pages 118-119, Mc Graw-Hill 1988.

If the antenna is installed vertically, MA is for significant suppression the steep radiation that ensures short-wave long-range traffic and good VHF Soil supply is harmful.

Claims (7)

1. Magnetic antenna, with an antenna conductor in the form of a ring, the circumferential length of which is preferably less than λ / 2, characterized in that the antenna conductor ( 1 ) is separated to form two radiation sources at two diametrically opposite points and into the two separation points (T1, T2) a capacitance (C1, C2) electrically connecting the adjacent ends of the two ring halves ( 1 a, 1 b) is inserted, the two ring halves ( 1 a, 1 b) forming the radiation sources each being smaller than are λ / 4 and the two capacitances can be tuned and one of the two separation points (T1) serves as an energy feed-in or output coupling point. 2. Antenna according to claim 1, characterized in that the both capacities have the same value. 3. Antenna according to claim 1 or 2, characterized in that each of the two capacitances (C1, C2) - compared to a magnetic one Reference antenna of approximately the same dimensions and with only one separated ring and with a tuning capacity inserted in the separation point - has about twice the capacity value as the voting capacity of Reference antenna. 4. Antenna according to one of claims 1 to 3, characterized in that in the area of the energy coupling-in and coupling-out point (T1) the capacitance (C1) consists of at least two partial capacitances (C11, C12) connected to one another in series, in the case of two partial capacitances (C11, C12) the center tap ( 2 ) lying between their one pads (a, b) as the one pole (P1) and the other pad (c) one of the two partial capacities (C11, C12) as the other Pole (P2) is used to connect a feed or decoupling cable ( 3 ). 5. Antenna according to claim 4, characterized in that the center tap ( 2 ) is grounded. 6. Antenna according to claim 4 or 5, characterized in that the feed or decoupling cable ( 3 ) to the two poles (P1, P2) is connected via a small tuning capacity (C3). 7. Antenna according to claim 4 or 5, characterized in that with the two partial capacitances (C11, C12) a further tunable capacitance (C13) or (C14) are connected in series, these additional capacitances (C13, C14) Adjustment of the center position of the current maxima (I _max ) on the ring halves ( 1 a, 1 b) are provided.