DE2323218C3 - Method and arrangement for determining the direction of incidence of sky waves - Google Patents

Description

The invention relates to a method for determining the direction of incidence of space waves with a Double-channel direction finder using one of two vertical frames arranged at right angles to one another and a horizontal frame existing DF antenna system.

In patent specification 11 88 680 there was a radio direction finder arrangement been described, which designed it, the incidence direction of a bump at the same time To determine reception of a sky wave out of phase with the ground wave. That was because of it has been made possible that the cross frame used for radio direction finding contrary to the known arrangement according to the invention, two vertical frames were arranged so that one of the two frames was horizontal lies. This frame arrangement has a cross frame that consists of two vertical frames physically completely new properties detailed in the text, which for the first time lead to a technically simple and at the same time very precise bearing of the bump with simultaneous incidence of a Have caused a sky wave. The criterion for the bearing was the result of the interaction from ground and sky waves into a line display by simply rotating the with a Azimuth scale provided vertical frame such that one of its zero points in the direction of incidence of the Bump points.

Experience has now shown that it is not in all In some cases it is possible to obtain reliable radio direction finding with this known arrangement, in particular then not if the incident sky wave itself is already elliptically polarized and at the same time a reflection from the ground learns.

It is therefore the object of the invention to provide the radio direction finder arrangement described in patent specification 11 88 680 to develop further in a way that is also suitable for this case.

The inventive solution to this problem is that the voltage of the horizontal frame after multiplication with the z. B. cotangent of the elevation angle generated by a variometer ■ & divided by means of a goniometer in the ratio of sin α and cos λ and each of these two partial voltages with opposite signs is added to each of the two vertical frame voltages and that the two resulting voltages the two channel inputs of the Double-channel direction finder are fed, where α is changed until a line-shaped bearing display that corresponds to the direction of the moving coil of the goniometer is changed on the screen of a Braun tube. This measure ensures that when λ = ρ (ρ is the azimuth of the wave), the voltages at the two channel inputs become in phase.

A simple arrangement for performing the method according to the invention consists of one Double-channel direction finder with a vertical cross frame that can be connected to its inputs and a horizontal frame. According to the invention, the output of the horizontal frame 3 is via a variometer 7 or Like. To the moving coil 8 of a goniometer 9, the field coils 10, 11 each to one of the outputs of the vertical cross frame 1, 2 are connected in such a way that the goniometer voltages coincide with one another add opposite signs to the voltages of the vertical frames.

In a further development of the invention it is also provided that in addition in the line between the variometer and a phase shifter 12 is switched on in the moving coil of the goniometer.

As a result, as will be explained in the following, in the case of a floor reflection of the sky wave eiwa occurring phase-unequal voltage components made in-phase.

The invention is explained below with reference to the drawings. It shows

Fig. I is a schematic representation of the field configuration when a sky wave hits the bearing location,

2 shows an arrangement for carrying out the method according to the invention,

F i g. 3 the special field configuration with ground reflection.

The antenna system required for finding any polarized sky waves consists (Fig. 2) of one fixed cross frame formed from two mutually perpendicular vertical frames 1,2 and one Horizontal frame 3 with the additional arrangements described below.

If you decompose the magnetic field (Fig. 1) one

elliptically polarized space wave into a horizontal one component

fit, ' sin ωι

and in a vertical component lying in the plane perpendicular to the direction of propagation and perpendicular to Hh

Hy sin (ü) i + ό),

so the phase angle ό and the amplitude ratio Η /,; Hy decisive for the axis ratio of the resulting ellipse and the position of its major axis. For a bearing with the cross frame formed from two vertical frames perpendicular to each other lies

Hh ■ sin t / ji

correct, while the one lying in the horizontal plane component

Hv ■ cos Il ■ sin (ωί + ό)

(ö is the elevation angle of the wave calculated from the vertical) bearing errors and rotating fields are generated. If ρ is the bearing azimuth, then with the above designations are the voltages induced in the cross frame

LZ ₁ = H _h ■ cos ρ · sin mi

+ H ₁ . Cosö ■ sin / 7 sin (f.if + Λ) j |)

U ₁ = H _h ■ sin ρ ■ sin <- <t

- W ₁ . ■ cos »? ■ cos ρ ■ sin {i »t + Λ)

and the tension of the horizontal frame
U ₁ , = W ₁ . ■ are ■ sin (mi + Λ)

The two voltages U 1 and U _{2 of} the vertical frame according to formula (1) would be fed to the two amplifier channels 4 and 5 of the visual radio direction finder according to FIG. 2 applied, result in an elliptical display on the screen of the Braun tube 6. The generation of a line-shaped bearing display true to azimuth requires the addition of the voltage Un of the horizontal frame according to formula (2) after the transformation described below. To convert the elliptical screen display into the line display characterizing the bearing azimuth ρ, according to the invention the voltage L // f induced in the horizontal frame is first converted into the voltage with the aid of a variometer 7

Uli = U ₁ , coti? = W ₁ . · Cosi? · Sin [t ,, t + />) (3)

This voltage U'n is then transmitted according to the invention to the moving coil 8 of a goniometer 9, from whose field coils 10 and 11 the voltages U'n · act λ and Un cos λ are taken when its moving coil is rotated by the angle λ. According to the invention, the channel amplifiers 4 and 5 of the radio direction finder finally receive the voltages

U ₁ = Ui - V ₁₁ ■ sin λ

U ₁₁ = U ₂ + U '"■ cos λ

fed. The algebraic addition of the voltages taken by the goniometer 9 with opposite signs in each case according to Eq. (4) is marked in Fig. 2 by + or -. One recognizes that if and only if * = ρ, i.e. the displacement force <\ of the moving coil, the bearing angle! ρ corresponds to the in-phase channel voltages

and

LZ, =

, · Cos /) · sin

U ₁₁ = W _A · sin ρ ■ sin

ίο are received, which on the screen 6 of the Dual-channel visual direction finder one in bearing azimuth ρ Generate horizontal line display.

The channel voltages (5) required for the line display generated in the bearing azimuth thus arise, by according to the invention by the described additional arrangement of a variometer 7 and one Goniometer 9 in the horizontal frame circle 3, the tension components harmful to the tension caused by the second term in formula (1) are identified.

2 «can be eliminated.

The radio direction finder described above for the direction finding of electrically polarized sky waves also has the property that the line display obtained, which directly shows the bearing azimuth, is completely unambiguous, i.e. h _M that, according to the invention, when direction finding with this radio device, in contrast to all other direction finding methods, no separate side determination is required. You can easily convince yourself of this by inserting the values for U \ and U ₂ from (1) and the value for L / 7i from (3) into formula (4) for the channel voltages U \ and Uu:

U _x = H _h ■ cos ρ · sin mf

+ [W ₁ . · Cosi? Sin ρ - W ₁ . · Cosi? Sin \] sin (e </ + Λ) ^r > (6)

U _n = H _h ■ sin ρ · sin ml
- [W ₁ . ■ cosö · cos ρ - W ₁ . · Cos /? ■ cos λ] · sin (<· / (+ Λ)

While for «= ρ the square brackets and thus the second terms disappear and the correct pin bearing (5) is obtained, the second ones still exist for all other azimuths, but especially also for the azimuth against the bearing direction tx = * ρ + 180 ° Links and thus the elliptical bearing display.

The radio direction finder arrangement according to the invention also permits the direction finding of linearly polarized space waves. In this special case is in equations (6)

-, ο phase shift δ = 0. The line displays then consistently obtained because of the phase equality of both elements are always afflicted with a bearing error if, in addition to the bearing-harmless component of the horizontal field strength W _{n, they have} a bearing-damaging component resulting from the vertical field strength H _1.

Which normally consist of both parts «-, together

The “coherent” strokes in the setting only change into the “pure” strokes in the bearing azimuths ρ _{if W 1 is} suppressed, ie if the differences in

bo the square brackets of formula (6) for U \ and Uw = 0. This is the case if the goniometer coil is rotated until the line display on the screen of the visual radio direction finder reverses its direction of rotation. This border position supplies from the abundance of

b5 "coherent" line displays as a bearing criterion "Pure" line: The display obtained in this inversion corresponds to the bearing azimuth p, which is directly on the The sight tube can be read.

Finally, the radio direction finder arrangement described also allows for error-free direction finding of any desired type polarized space wave when it experiences a ground reflection (Fig. 3). by according to the invention in Horizontal frame circle (Fig. 2) also inserts a phase shifter 12, the mode of operation in is explained below.

The decomposition of an elliptically polarized space wave into two linearly polarized waves with the phase shift Ά resulted, as was shown above, a magnetic vector // and a magnetic vector // ,. which is perpendicular to ///, and lies in the collapse of the shaft.

If one considers the portions /// “and // of the two partial waves reflected from the ground. so the following applies: The magnetic vector of the reflected Tcilwcllc /// ,. lies with Hi, in the same direction, since the reflection does not cause any lateral deviation of the wave, lh and // ■■ ·. have an electrical phase difference depending on the soil constants, to which there is also a phase shift resulting from the different transit times. The resultant

/ 7 ,, = Hi, + Hi,

but in any case points in the direction of H ·. The vector Hh does not produce a bearing error.

The magnetic vector H _{x of} the reflected partial wave, like H _{1, is also} in the final plane of the wave. In general, however, both vectors do not have the same direction in space and, as a result of the reflection conditions and the differences in timing, also have a phase shift from one another. The spatial vectors / 7, and H, _r therefore together form an elliptical rotating field located in the plane of incidence of the wave. This elliptical rotating field leaves

*> can now also be described by two other vectors, namely a horizontal one with the amplitude A. which acts on the vertical frame and a vertical one with the amplitude B that is only recorded by the horizontal frame. Compared to the vector H _m may

in A have a phase shift Λ + ψ and B a phase shift of Λ + iji. Then the voltages of the two cannulas of the visual radio receiver are:

(ι clock, - ' cos P ' sin '■'
■ t- II sin /; · Sin l · ·. / + Λ t <_; ) /} ■ sin \ · siiil «·· / t λ t _v

",, //) ,,,., sin / 'sin nt
f- ί -iu is / ι ■> iii f> ■ · / t 'Ί t ij j π

\ miiw · ϊ 4 / ι t >,

One now makes with the help of the variometer 7 B = A lying in the course of the horizontal frame and with the help of the according to the invention. As explained, phase shifter 12 also located in this context

y, ti = I ₁ : then with the help of the goniometer in the position \ = ρ of its moving coil the members of the square brackets of the formula (7) are eliminated and again in-phase voltages analogous to the formula (5) are obtained. as explained on the

Generate line display located in the bearing azimuth ρ on the screen.

For this purpose I sheet drawings

Claims (3)

Claims; 1. A method for determining the direction of incidence of sky waves with a double-channel direction finder ϊ using a bearing antenna system consisting of two vertical frames arranged at right angles to one another and a horizontal frame, characterized in that the voltage of the horizontal frame after multiplication with the z, B. by a variometer generated cotangent of the elevation angle fr divided by means of a goniometer in the ratio of sin «and cos α and one of these two partial voltages with opposite signs is added to one of the two vertical frame voltages and that the two resulting voltages are fed to the two channel inputs of the double-channel direction finder where α is changed until a line-shaped bearing display that corresponds to the search coil direction of the goniometer appears on the screen of a Braun tube. 2. Radio direction finder arrangement for carrying out the method according to claim 1, consisting of a 2> double-channel direction finder with a vertical cross frame connected to the inputs of the double-channel direction finder and a horizontal frame, characterized in that the output of the horizontal frame 3 via a variometer 7 or the like. to the moving coil 8 of a goniometer 9, whose field coils IU, 11 are each connected to one of the outputs of the vertical _{cross frame I 1} 2 so that the green meter voltages with mutually opposite '■' signs add to the r> voltages of the vertical frames . 3. Radio direction finder arrangement according to claim 2, characterized in that the lines between the Variometer 7 and the rotating coil 8 of the goniometer 9 a phase shifter 12 is switched on. 4 »