DE2401161B2 - PILOT SYSTEM WITH AZIMUTE PILOT BEHIND AND ELEVATION PILOT NEXT TO THE RUNWAY - Google Patents

Description

State of the art

The invention relates to a direction finding system for a landing system in which the on-board station has RF signals radiates and the navigation data is determined on the ground and transmitted to the on-board station, consisting of an azimuth direction finder located behind the runway and an elevation direction finder located next to the runway.

Such a direction finding system is known from DT-OS 20 38 982. The locations of this plant are Azimuth direction finder and elevation direction finder roughly the same as those of the landing course transmitter and glide slope transmitter of the instrument landing system (ILS). During the landing maneuver, the aircraft goes about 30 m from the approach to the Float over. The lift-out distance to touchdown is about 1200 m, in the middle of this For this reason, the glideslope transmitter is located on the route, the antenna of which radiates in the approach direction Elevation cannot be measured between the glide slope transmitter and touchdown point, but this is possible for blind landing systems is absolutely necessary To make this possible, it is known to have a second glideslope transmitter to be provided next to the runway at the touchdown point. Such a second glideslope transmitter is laborious.

task

It is the object of the invention specified in the claims, a direction finding system for a Specify the landing system with the distance of the aircraft from the touchdown point, the altitude of the aircraft and the elevation when floating out, based on the touchdown point, can be precisely determined.

advantages

With the direction finding system according to the invention, only one elevation direction finder is required. On the plane one can In principle, there is no need for high-precision radio altimeters.

description

The invention will now be explained in more detail with reference to the drawings, for example. Show it

Fi g. la and Ib show a plan view and a side view a runway with azimuth and elevation direction finders and a flight profile of a landing aircraft,

2a and 2b show the geometric relationships between the objects shown in Fig. la and Ib,

F i g. 3a to 3d show the schematic representation of four possible antenna arrangements for the elevation direction finder and

F i g. 4 is a block diagram of an elevation direction finder.

In Fi g. la is in plan view and in FIG. Ib is the side view of the flight profile of an aircraft that is currently at point F and wants to land on a runway B. When approaching the aircraft to the predetermined landing course swings which generally equal to the extended approach ground line C, which is identsich with the runway axis The aircraft radiate radio frequency signals that are received by an elevation direction finder G and an azimuth direction finder L. The azimuth direction finder is located on the approach baseline on the opposite side of the runway to the approach path. During approach (F to D), float (D to A), touchdown (A) and taxiing, it determines azimuth # 1 between the straight line connecting the aircraft and azimuth direction finder L and the approach baseline C.

In addition to the runway, in the middle between the point D, in which the aircraft beginni with the flare and the point of application A on the runway, the elevation direction finder is G. During approach aiming the aircraft at the selected elevation φ of the point / / the runway to which the Gquerab elevation direction finder is located.

In Fig. 2b it is assumed in simplified form that the point G is located in the plane of the runway, in reality the antenna arrangement is located

Elevation direction finder, however, above this level. At about 30 m (about 600 m in front of the elevation direction finder) the aircraft begins to float out, i.e. That means, it reduces the rate of descent. It touches down on the runway at point A about 600 m behind the levitation direction finder.

The azimuth direction finder and the elevation direction finder, as far as they have been described so far, are known and will be therefore not explained in more detail.

In order to be able to determine the parameters required for guiding the aircraft during floating, namely the distance e of the aircraft from the touchdown point A and the height h above ground (Fig. 2a, 2b), the elevation direction finder G is used instead of a directional antenna arrangement directed in the approach direction according to the invention one of the antenna arrangements shown in FIGS. 3a to 3d; These each consist of an omnidirectional antenna arrangement for measuring the azimuth ϋ-2 (Fig. 2a) related to their location and at least one antenna line covering the approach sector and the entire runway for measuring the planar elevation φ and the conical elevation φ '. The various antenna arrangements are described below.

The geometric relationships between the quantities sought and the known quantities are shown in the F i g. 2a and 2b, where F i g. 2a to FIG. la and F i g. 2b belongs to Fig. Ib.

In the triangle LHG all quantities are known, namely the distance LH, which is composed of the distance ei of the azimuth direction finder L from the touchdown point A and the distance ei of the point H to the touchdown point A , the distance d \ of the elevation counter G from the approach baseline C, the Distance LG, which is equal to the distance ώ of the azimuth direction finder L from the elevation direction finder G and thus also the angle at L, which is denoted by γ , and the angle at G, which is denoted by η. The landing direction finder determines the azimuth ϋ · \. The following auxiliary variables are also required for the calculation: f, the horizontal distance between the approach baseline C and aircraft F; ei, the distance between point H and the intersection of / with the approach baseline Q b, the horizontal distance between touchdown point A and aircraft F; a, the horizontal distance between the elevation direction finder G and aircraft F.

Using the equation

^sin

COS [O ₁ + I) ₂

the first size you are looking for is calculated, the height h from:

h = a tg? '.
With the help of this quantity follows

_t ■) _

is further

/ = Ic ₁ f C ₂ t t'_,) tg .1 ,.

λ = fnT (c7Vc ^ '.

The second size sought, the true distance of each aircraft F from the touchdown point A, is thus calculated

= l '/ r + if.

In addition to or instead of the distance e, the elevation φ "of the aircraft F related to the touchdown point A can be calculated:

The equations for the sizes we are looking for can be

is also derived with ώ.

F i g. 3 shows four different antenna arrangements for the elevation direction finder. The first and the second possibility is a vertical line 1 which measures the conical elevation φ ' and which is supplemented by a line cross 2, 3 (FIG. 3a) or by a horizontal circle group 4 (FIG. 3b), with which Measure the angle # 2 and convert the conical elevation φ ' into the planar elevation φ. Instead, you can also place the horizontal line cross 2, 3 or the circle group 4 on four supports (5 to 8), two of which, namely the supports 6 and 6, are designed as vertical lines with directional slot radiators. Line 6 is used for measurement in the approach direction and line 5 for measurement in the runway direction. The antennas of all other rows and the circle group are omnidirectional.

F i g. 4 shows a block diagram of the elevation direction finder G, in which the antenna arrangement according to FIG. 3 3a) is used. The RF signals transmitted by the aircraft on-board station are received by the antennas in lines 1, 2 and 3 and each reach a receiver multiple 9, 10 and 11, each of which has as many receivers as the line of antennas. In downstream phase meters 12, 13 and 14, the phases of each signal are determined individually and the mean value is formed, so that phase values JJi, / te and 03 appear at the outputs. After analog / digital conversion, the phase values are transferred to a high-speed digital computer 15, in which, in a first step, with the aid of the equations

Ig x 7 =

eat / 12

(10)

the angles φ, φ 'and # 2 are determined. The azimuth # 1 measured by the azimuth direction finder is also fed to the computer. Thus, in a second step, the computer can use equations (1) to (7) to calculate the required variables h and e and possibly φ " . A transmitter 16, the RF signals of which is emitted by an antenna 19, is modulated with the calculated variables The signals are received, evaluated and further processed by the on-board station.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. DF system for a landing system in which the on-board station emits HF signals and the navigation data is determined on the ground and transmitted to the on-board station, consisting of an azimuth direction finder located behind the runway and an elevation direction finder located next to the runway, characterized in that the elevation direction finder ( G) is equipped with an antenna arrangement receiving in the three coordinate directions, with which, in addition to the planar elevation (φ), the conical elevation (φ ¹ ) and the azimuth (fo) related to the location of the elevation direction finder (G) are measured, and that from the measured values (φ, φ ', fc), the geometric values of the triangle created by the locations of the azimuth direction finder (L), the elevation direction finder (G) and the point of intersection (H) of the perpendiculars on the runway through the elevation direction finder and the runway is determined, and the azimuth determined with the azimuth direction finder (# 1) the altitude (b) of the aircraft and the distance (e) of the aircraft from the rise touchdown point (A) and / or the elevation (φ ") of the aircraft related to the touchdown point can be determined. 2. DF system according to claim 1, characterized in that the antenna arrangement consists of one horizontal line cross (2, 3), in the middle of which another line (1) vertically upwards is arranged, with all antennas being omnidirectional. 3. DF system according to claim 1, characterized in that that the antenna arrangement consists of a horizontal antenna circle (4), in which In the middle of a row (1) is arranged vertically upwards, with all antennas being omnidirectional. 4. DF system according to claim 1, characterized in that the antenna arrangement consists of one horizontal line cross (2,3) with omnidirectional antennas, each at one end another row (5, 6) with directional antennas is arranged vertically downwards. 5. DF system according to claim 1, characterized in that the antenna arrangement consists of one horizontal antenna circle (4) with round receiving antennas and two vertically downwards arranged and on the circle offset by 90 ° lines (5, 6) with directional antennas consists. 6. DF system according to one of the preceding claims, characterized in that the of signals received by all antennas simultaneously by phase or by phase and amplitude be evaluated.