DE1258922B - Adcock, in which an undirected auxiliary voltage is obtained - Google Patents

Description

Adcock, in which an omnidirectional auxiliary voltage is obtained. The invention concerns an Adcock, in which the currents flowing in the Adcock become undirected Auxiliary voltage is obtained.

In general, the auxiliary voltage is used for the side identification or Clearance obtained with the help of an auxiliary antenna. However, it is also already known with an Adcock connected to a goniometer or a coordinate transformer is, an omnidirectional voltage by utilizing the vertical antenna effect win (German patent specification 706 538). The centers of the field coils are used for this of the goniometer is earthed in terms of high frequencies, and from the currents flowing to earth the undirected tension is obtained. Use is a prerequisite for this a goniometer or coordinate transformer. However, a goniometer is off Bearing reasons are by no means always necessary, for example when you have a four-man Adcock used with a two-channel direction finder. The additional use of an expensive goniometer only to obtain the undirected voltage is not for reasons of expense to represent. Also, the use of goniometers at very high frequencies disadvantageous because of the poor coupling in the goniometer.

The object on which the invention is based is, under Avoidance of a goniometer or coordinate transformer, i.e. avoidance a limb that reduces the sensitivity of the bearing system, to an Adcock create, in which, in addition to the DF voltage, the non-directional auxiliary voltage is also obtained can be.

This problem is solved by the fact that between the corresponding Terminals of the two individual antennas of the adcock and the decoupling points a line transformer (transformer with Line characteristic is switched on and that one with at least one line transformer coupled tertiary winding is provided in which the non-directional auxiliary voltage is tapped.

As mentioned above, you can do the tertiary development with either of the two Couple line transformer.

However, it is more advantageous to design the tertiary winding in two parts, each winding part is coupled to a line transformer, and then to connect the two parts of the line in parallel or in series. The series connection has the advantage that the auxiliary voltage is generated by the summation is enlarged. It goes without saying that the Adcock according to the invention also for use in multiple Adcock systems men can. The individual antennas can also consist of two antennas connected in parallel.

The invention is to be explained in more detail with reference to the drawing. In FIG. 1 of the drawing are the voltages of the individual antennas of an Adcock shown vectorially and designated with U1 and U2.

The two voltages U1 and U2 can be divided into in-phase components Divide Ulg or U9g and into antiphase components Uie or U2e.

In Fig. 2 shows a typical Adcock. It consists of the two dipoles 1 and 2, their voltages due to the crossover in the connecting lines are switched against each other. The bearing voltage is tapped at resistor 3. In FIG. 2 the currents flowing in the Adcock are indicated by arrows. These Currents are caused by the antiphase components of the antenna voltages. The phase opposition of the voltages generating these currents is shown in FIG different signs indicated. In the arrangement of FIGS. 2 are in phase Components shorted. They don't create tension. So it cannot be undirected Voltage can be tapped at the Adcock.

3 shows an exemplary embodiment of one implemented according to the invention Adcocks depicted.

As already mentioned above, with the Adcock according to the invention without Influencing the DF voltage also an omnidirectional auxiliary voltage can be obtained. Two line transformers 4 and 5 are also provided for this purpose. Appropriate Connection terminals of the individual antennas, i.e. those with the upper halves of the dipoles 1 and 2 connected terminals are connected to the line transformer 4th connected, while the terminals connected to the lower dipole halves are connected to the line transformer 5. Both line transformers are with their second pair of connection terminals connected to the load resistor 3. The from the antiphase components of the antenna voltages (again with plus and minus signs indicated) caused currents are again shown in dashed lines. Man recognizes that they flow through the line transformers 4 and 5 in opposite directions. The line transformers thus have no influence on these currents, i. i.e., for the The line transformers 4 and 5 are practical for the currents generating the DF voltages unavailable.

The in-phase components of those produced in the individual antennas Voltages generate the currents shown in FIG. 3 by solid arrows. The phase position of the in-phase components is indicated by plus- (+) or minus sign () expressed. Due to the connection of the dipoles 1 and 2 to the line transformers 4 and 5 is achieved that those of the in-phase Components of the antenna voltages generated currents the line transformers in the same direction flow through. The currents thus cause a flood in the same direction.

This flow in the same direction is used to attract the undirected Tension exploited. In the embodiment of FIG. 3, there is a two-part tertiary winding provided, the winding parts 6 and 7 with the two line transformers are coupled. The two winding parts are connected in series switches what one at the output terminals of the series connection a sum voltage, which is made up of the composed of voltages induced in the individual winding parts 6 and 7. This voltage tapped at the output terminals of the series connection is practical direction-independent and can therefore be used as a non-directional auxiliary voltage.

It is of course also possible to use dipoles 1 and 2 of F i g. 3 to be replaced by vertical radiators excited against earth. The in the F i g. 3 interconnection shown is then no longer with the terminal pairs of the Dipoles 1 and 2, but connected to the two pairs of terminals of the vertical radiator.

Claims (2)

Claims: 1. Adcock, in which from the flowing in Adcock Currents an undirected auxiliary voltage is obtained, characterized by that between the corresponding terminals of the two individual antennas of the Adcocks and the decoupling point for the DF voltage from the Adcock Line transformer is switched on and that one with at least one line transformer coupled tertiary winding is provided to which the non-directional auxiliary voltage is tapped. 2. Adcock according to claim 1, characterized in that the tertiary winding Is designed in two parts and the two winding parts in parallel or in series are switched.