DE629606C - DF antenna system - Google Patents

Description

DF antenna system It is often necessary to use an undesired one when taking direction finding to eliminate interfering components. Such a case comes e.g. B. before if a Radiation reflected by the so-called Heaviside layer is taken from the ground, for example must become. In this case it has already been suggested to use the Peilrahmenan: enne to combine a dipole antenna, which as well as the loop antenna with the input circuit of the receiver is paired. Such an arrangement is shown in Fig. I. Here a denotes the frame circle, e the dipole, c the coupling elements and d the input circle Recipient. Is it about the disruptive effect of a rotation the polarization plane of the received wave when it is reflected on the Heaviside layer resulting horizontal component of the magnetic field to the minimum reception to eliminate, so you can with appropriate dimensioning of the horizontally arranged Dipole e and adjustment of its coupling by the action of this dipole on the Secondary circuit d override an emf, which is just the damaging, through the frame a transmitted unwanted component compensated.

A compensation device designed in this way has the disadvantage that it only works properly at a certain wavelength, for everyone else but must be readjusted, either by changing the dipole or by changing it its coupling.

According to the invention, means are now provided for such an adjustment to make the compensation unnecessary when transitioning to another wave. To this The purpose of this is to couple the frame and the dipole to the receiver in such a way that the bearing is at the minimum the mutually canceling tensions, namely that of the frame and that of the Dipole originating, depend in the same way on the frequency, z. B. in the same Way to fall or rise with frequency. With such an arrangement then the two values to be compensated always have the same size, regardless of the frequency.

Two embodiments for different variants of the invention Arrangement are shown in Fig. A and 3.

In the arrangement according to Fig. Z, only the frame circle a with the Secondary circuit, l coupled by a suitable coupling element (transformer c). The frame circle is cut open and the two halves are at the dividing points of the dipole e connected: At the same separation points can expediently a capacitor b of suitable size can also be connected. In the bearing minimum must the secondary circuit d will be de-energized. That is only possible if there is also electricity in the Frame circle a does not exist. For this purpose the dipole is used e or capacitor b dimensioned so that the occupancy of the latter through the voltage induced by the frame circle of the voltage imposed by the dipole, _ Keeping balance. If you have this desired "effect for eüit". Certain reception wavelength brought about, it is also maintained at other reception frequencies, because if the arrangement described is built on a highly conductive earth, the in the frame circle and the voltages induced in the dipole proportional to the frequency grow.

Another arrangement is shown in Fig. 3.

Here, too, a means the frame that is connected to the transformer c the receiver circuit d is coupled. .e is again the dipole; he's about one special transformer f coupled to the receiver circuit d. The compensation effect is also dependent on the frequency here if the eigenwave of the dipole circle and the natural wave of the frame circle made the same or approximately the same size are. For this purpose, a capacitor b of a suitable size is placed in the frame circle switched on. At the bearing minimum, circle .d is again without current; so here are the frame circle and the dipole circle are not coupled to one another. Those in these circles -flowing currents depend therefore only ever on their own induced by the received wave EMKK and on your own impedances; since the natural waves of the two cresses are the same are large, the ratio of the currents is independent of the frequency, if that. The ratio of the EMFF in itself is independent of the frequency, which is the case with good conducting Ground is the case. But if the ratio of the currents in the circles ä and: e is independent of the frequency, so is the ratio of these currents mutually compensated voltages induced in the currentless receiver circuit d. So if the compensation is correct for a given frequency, it is correct for all other frequencies, unless it is the resonance frequency. In In this second case, the attenuation must also be the same for both circles, so that the "X" compensation is still correct.

In order to obtain sufficient reception strength, it is advisable to use the Natural wave of the two antennas around 2o to 5o from the middle one. Length of the bearing wave to choose differently.

The eigenwave of the two circles can also be deliberately slightly different to compensate for the influences of the soil.

Claims (2)

PATENT CLAIMS: r. DF antenna system with a loop antenna and a dipole antenna compensating for interfering components, characterized in that that the dimensions and mutual connection of the two antennas are chosen so : that the mutually compensating for the secondary circuit excited by these antennas Voltages depend in the same way on the wavelength of the incoming radiation, z. B. in that the loop antenna coupled to the secondary circuit alone is cut open is (if necessary with connection of a capacitor) and that to the separate Ends the dipole antenna is connected (Fig.2) or by the loop antenna (in the circle of which there can be a capacitor) and the dipole antenna each separately are coupled to the secondary circuit and have essentially the same natural waves (Fig.3). 2. DF antenna system according to claim i, characterized in -that in the case of Arrangement with separate coupling of the two antennas on the secondary circuit Natural waves deviate by about 30% from the mean length of the bearing wave. .