DE537464C - Bearing beam transmitter with pendular moving beam cone - Google Patents

Description

In order to obtain a very sharp bearing beam, it is advantageous to use a differential arrangement specified by Kiebitz. It consists in that two cones of rays that are not very sharp are emitted side by side, so that the following known diagram is produced (FIG. 1): Curve I denotes the ray diagram associated with the first cone and curve II the diagram associated with the second cone; both cones are now placed next to each other in such a way that their diagrams intersect at the steepest points. The transmitters belonging to the 'cones I and II send out characters that generate a continuous wave at the same amplitude, e.g. B. α and n. A receiver would therefore receive a continuous wave at point P in FIG. 1, while the symbol associated with cone I would predominantly be registered _{at point P 1} and the symbol associated with cone II would be registered _{at point P 2.} This arrangement still shows certain disadvantages, which consist in the fact that the energies of the transmitters belonging to the two beam cones must be absolutely constant and of the same size.

However, these conditions cannot be met in practice. This results in considerable Peilsträhl's misdirections.

In order to achieve the greatest possible symmetry of the arrangement, the inventor proposed to use only one exciter which is located in the focal point of a concave mirror and to let this oscillate with the exciter by an angle α. The mirror should stay in cone I for a long time and in cone II only for a short time. If a sensitive pointer instrument was used on the receiver, the deflections for points P, P ₁ and P _{2 shown} in FIG. 2 are obtained when a compensation arrangement is used.

According to the invention, the same result can be achieved can be achieved if the exciter and mirror are not allowed to oscillate at the same time, but rather either arranges the pathogen in a fixed position and lets the mirror swing by itself, or vice versa. The latter arrangement, in particular, can be very advantageous in practice if, for. B. for very short Hertzian waves is forced to use very large mirrors. You need then the mass of the heavy mirror is not in To set movement, but only to let the pathogen oscillate, its mass however can always be kept low.

3 shows a schematic representation for this case. S is the fixed mirror, -E the exciter, which oscillates around the focal point and around the angle α. If E is in position 1, it emits diagram I; if, on the other hand, it is in position 2, it emits diagram II. So you get the same diagram image

as in Fig. ι and correspondingly the same deflections of the reception indicator, as shown in Fig. 2 is shown. S ₁ means a small mirror, which should concentrate the energy of the exciter S as much as possible on the surface of the large mirror S and expediently simultaneously with the exciter (e.g. spark gap, tube, temperature radiator, etc.). commutes around the focal point. However, it is not necessary that the pathogen, be it with or without mirrors S _1, exactly symmetrical swings around the focal point, but the value can be ~

are also out of focus, but in practice one will find oneself out of economic Do not remove the reasons too far from the focus.

It has been shown that when turning the mirror or in the present If the pathogen receives disturbing curves, which have to be compensated; this is best done by dimming. Loading. The compensation or dimming device in the front is particularly easy.

shape lying trap. According to Fig. 4 there is a very small fixed shielding mirror Z between the mirror wall S and the excitation system E ₁ S ₁ , which partially shields the rays in the middle position: if, on the other hand, the excitation system is in positions 1 or 2, the rays from Z are not more impaired. When using an exciter for very short waves, it is advisable to use a metal rod of about -

Length. By adjusting the distance Ζ-Έ , the compensation can be set very precisely.

Claims (4)

Patent claims: 1. Bearing beam transmitter with pendulum moving Beam cone, in particular for wireless navigation ", characterized in that that there is an excitation system (spark gap, three-electrode tube, temperature radiator etc.) relative to the focal point of a mirror oscillating through an angle. 2. Bearing beam transmitter according to claim i, characterized in that the oscillating Excitation system relatively in one end position for a long time and in the other end position persists for a short time. 3. DF transmitter according to claim r and 2, characterized in that at the same time as the excitation system moves a mirror firmly connected to it, which partially shields the rays in the middle position. 4. DF transmitter according to claim 1 to 3, characterized in that a very small shielding mirror on the center line near the excitation system like this is arranged that a compensation of the disturbing curves occurs. For this purpose I sheet drawings