DE704449C - Method for creating a route for aircraft - Google Patents

Description

Method of Establishing a Route for Aircraft The present The invention relates to a method for forming a route for aircraft, that of paraboloid-like, overlapping ones and the one common in aircraft Flying altitude expanding omnidirectional radiation, so-called radio beacons, exists, which on are distributed along the route.

To direct aircraft on a route is already it has been proposed that these be highly bundled with a number in one direction Occupy vertical radiation.

The radiation should be designed so that horizontal cuts result in narrow ellipses and that the longitudinal axes of these ellipses in the direction of route to be marked. Such, characterized by vertical radiators Roadways are naturally very narrow. Due to the occurring in aircraft at high airspeeds, it requires great attention on the part of the driver To pause such narrow streets carefully. Furthermore, that is covered by the radiation spatial angle with vertical orientation of the radiation is very small, so that a relatively large number of single emitters is required to create a driveway mark.

In contrast to this method, the present invention provides one Improvement.

There, as already mentioned, omnidirectional radiation to form a route Should be used, the diagram of this omnidirectional radiation according to the present Invention be flattened on the zenith side so that the area of reduced vertical intensity becomes as small as possible over the radiation center.

The radius of action of such an omnidirectional radiator is considerably larger than that of a vertical radiator, so that a certain distance compared with the above-mentioned method with a smaller number of radiators occupied needs to be.

According to the invention, the radiation diagram should be so deformed that the mini-umstelle in the vicinity of the omnidirectional center is as small as possible will. This is achieved in that the radiation is steep and steep towards the zenith side on the bottom side rises flat against the ground.

In itself is the use of omnidirectional transmitters for identification known from certain routes. It is also known to be paraboloid-like Provide radiation. Apart from the fact that one such radiation is to be used as a landing curve for aircraft, the radiation form is at the known device designed so that a very large zero zone in the radiation center is present, so that an airplane occupying one with such radiation Should keep the driveway, receives only brief signals from these radiations. These disadvantages are alleviated by the formation of the diagrams according to the present invention Invention avoided.

To identify the radiation centers, it is advantageous to use the secondary radiation (tips) occurring with every light radiation are used. However, the center of the radiation should be characterized by a zero reception zone the lobes can also be suppressed if necessary.

This makes it easier for the pilot to find neighboring emitters facilitated, since adjacent radiations overlap in certain areas. According to a further development of the arrangement according to the invention, in addition to a simplified one Aircraft management also provides a position determination in the Seine a distance determination are made possible by the fact that each omnidirectional radiator has a different identifier. z. B. by keying or other modulation.

It is not necessary. that the omnidirectional radiation is uniform and is sent out at the same time. It can also be achieved, for example, by a suitable bundle of rays, which at a small angle against the earth's surface is inclined to rotate about a vertical axis. This can be achieved thereby be that you can rotate the entire radiator or only the reflector or deflects the radiation onto suitable mirrors. One chooses the rotation speed of the individual bundles of rays different, so this results - already a distinguishing feature for each individual radiator, and additional modulation is superfluous. Takes it is assumed that for some reason certain pages or

Parts of the omnidirectional radiation must be specially marked. approximately as danger zones, one can either reduce the radiation in these sectors, e.g. B. by Dazzle, suppress or the radiation in these sectors a special modulation press on.

For example, in Figs. I to 3 there are three contiguous Rundstrabler shown, Figs. 1a, 2a, 3a represent one through the axes of rotation of the omnidirectional radiation.

Fig. Ib shows in the ground plan the sphere of activity of a rotating Ray bundle R.

Fig. 2b shows in the plan the local course of a uniform and at the same time working omnidirectional radiator.

Fig. 3b shows the local course of an omnidirectional radiation in plan represents, which suppresses H at an angle α to identify an obstacle or is conspicuously marked by special modulation.

Routes indicated by radiation diagrams according to the present Invention to be characterized are similar in structure and mode of operation the shipping routes marked by visible omnidirectional beacons. Accordingly it is advisable to use a receiving device that is compatible with the human gnaws with regard to the recording characteristics, d. H. its spatial reception angle corresponds roughly to the field of vision of the human face. A bundling of the reception characteristics is only to be carried out to the extent necessary for the pilot to control it comfortably is; So it will practically suffice to only point the receiving antenna towards the reception area shield from radiation coming from the direction of origin of the aircraft (from the area already flown over).

However, if a backward orientation is desired, the receiving device can be used or make the reflector screen switchable. On a suitable display instrument in the receiver output can then from the comparison of the signal strengths between overflown and emitter to the approximate distance of the aircraft from both getting closed.

Claims (8)

PATENT CLAIMS: 1. Method for creating a route for aircraft, that of paraboloid-like, overlapping and distributed over the flight route Expanding omnidirectional radiation (radio beacon) at the usual flight altitude for aircraft consists, characterized in that the diagram of this omnidirectional radiation ænithseiten is flattened so that the area of reduced vertical intensity is above the center of the radiation becomes as small as possible. 2. The method according to claim I, characterized in that the radio beacon location by the secondary radiation (tips) occurring in the radiation center is made. 3. The method according to claim 1, characterized in that the radio beacon location by suppressing the secondary radiation occurring in the radiation center (tip) and the resulting zero reception zone is identified. 4. The method according to claim 1 to 3, characterized, that each omnidirectional radiation is given a different identifier through keying or modulation. 5. The method according to claim r to 4. characterized in that the Omnidirectional radiation is caused by the rotation of a beam. 6. The method according to claim 5, characterized in that the flow speeds of the rotating beams of adjacent radio beacons are different. 7 The method according to claim 6, characterized in that the Omnidirectional radiation suppressed in certain directions or in certain sectors is. 8. The method according to claim 1 to 7, characterized in that certain Parts or certain sectors of an omnidirectional radiation through different modulation or and keying are marked.