DE2407975C2 - Modulation arrangement for amplitude modulation for a radio navigation system - Google Patents

Description

The present invention relates to a modulation arrangement for amplitude modulation for a radio navigation system according to the preamble of claim 1.

In certain antenna systems, mouulation signals are modulated in a predetermined phase relationship applied to a variety of antenna elements. For example, this is done with antenna systems, which are used in connection with the TACAN radio navigation system. With such known In antenna systems, the modulation is effected, for example, by mechanical drive devices.

From US-PS 34 74 446 an antenna system is known in which the modulation is effected electronically will. A disadvantage, however, is that the modulation takes place by being in the transmission line a variable loss is introduced according to the modulation pattern, with the result that a a substantial part of the input power is used uselessly. For example, in such modulation arrangements about half of the input power is consumed. In addition to the resulting low Efficiency is another disadvantage seen in the generation of heat, which leads to the service life certain components of the modulation arrangement is shortened.

The object of the present invention is to to improve a modulation arrangement as mentioned in the introduction to the effect that the power losses be kept as small as possible without affecting the radiation characteristics of the radiating elements is changed.

This object is achieved in a modulation arrangement according to the preamble of claim 1 by the im characterizing part of claim 1 specified features solved

The module arrangement according to the invention has a significantly longer service life than comparable ones known modulation arrangements, because as a result of the reduction in power losses during operation less heat is developed in the modulation arrangement.

The following are the invention and its embodiments explained in more detail in connection with the figures It shows

F i g. 1 shows a diagram of a typical radiation pattern of a system in which the modulation arrangement according to the invention can be used;
F i g. 2 shows a schematic representation of the modulation device according to the invention in connection with an omnidirectional radiation system;

F i g. 3 shows a schematic representation of an embodiment of a modulation arrangement according to the invention;

F i g. 4 shows a schematic representation of a further embodiment of a modulation arrangement according to the invention;

F i g. 5 is a perspective view of a modulation arrangement according to the invention; and

F i g. 6 shows a section along the plane 6-6 in FIG. 5.

The modulation arrangement according to the invention makes an RF radiation system with a large number HF energy jo supplied by radiating elements is modulated to a specific radiation pattern to reach. The radiation system has pairs of radiating antenna elements that are in phase opposition require modulated RF modulation signals. To the feed line for each antenna element of a pair Radiating antenna elements is a suitable semiconductor element which is a diode can, connected. In one embodiment, one semiconductor element is shunted to one at a time Line arranged. In a further embodiment, there is in each case a semiconductor element to a line connected in series. A modulation signal with an arbitrary but periodic waveform is sent to each of the semiconductor elements is applied, the modulation signal supplied to one semiconductor element of each pair in phase opposition with respect to the modulation signal applied to the other semiconductor element of the pair and has the same amplitude. This reduces the impedances of the semiconductor elements changed out of phase. As the lines for the power supplied to such a pair of radiating antenna elements originates from a common feed line connected to an HF generator, this causes antiphase Change the impedances of the two semiconductor elements that of the pair of radiating antenna elements supplied power varies accordingly between these elements, but the load for the common feed line remains constant. So it becomes the power among the pair of radiating antenna elements divided according to the modulation signals without other power losses that normally occur when a current flows through the elements. This is in contrast to the known systems, in which, with the desired modulation of the RF power, a considerable * proportion of the power in the b5 modulation arrangement is lost.

The assembly arrangement according to the invention can although they are in a system with a cylindrical radiation pattern, such as the TACAN system,

is particularly suitable, also with other radiation systems with one pair or with several pairs of radiating antenna elements, their output powers modulated out of phase with each other so: must, used to obtain the desired radiation pattern.

F i g. 1 shows a typical radiation pattern of a TACAN antenna in which the modulation arrangement according to the invention can be used. As can be seen, this exemplary radiation pattern has an odd symmetry, since there are nine lobes, the amplitudes of which vary sinusoidally in accordance with the modulation signal. This characteristic can be created with a cylindrical antenna of the type used in most TACAN systems. The characteristic is such that, when the signals vary continuously, the sum of the signals jn two diametrically opposite points of the radiation pattern, for example at points A and B of FIG. 1, remains constant. It should be noted that the points A and B selected for illustration are randomly located on the positive and negative peaks of the sinusoidal radiation pattern. However, the constancy of the sum also applies to all other diametrically opposed pairs of points, regardless of where these pairs of points are located in the characteristic. The radiation pattern rotates in the direction of arrow 11 as a function of the angle Φ. In order to express the constancy of the sum of the diametrically opposite points, the following equation can be used:

[Μ (Φ) - 1] = [1 - Μ (Φ + 180 °)]

M denotes the periodic modulation signal, which is typically sinusoidal.

F i g. 2 shows how the modulation arrangement according to the invention is used in connection with a TACAN system is working.

The transmitter 12 sends high-frequency energy at the system carrier frequency to the power splitter 15 via the coupler 14. The power divider 15, which is, for example, a strip power divider, divides the power n-fold, where η represents the number of pairs of radiating antenna elements of the system and a modulation arrangement 17 is provided for each of these pairs. There are therefore η modulation arrangements 17 and the power splitter 15 has outputs which lead to each modulation arrangement.

The same power components of the split output power come from the modulation arrangement 17 No. 1 to the pair of radiating antenna elements 19a, 196, which are arranged diametrically to one another. Corresponding each other modulation arrangement 17 supplies modulation signals to a further pair of radiating ones Antenna elements 20, some of these elements only being shown in dashed lines. Typically wise the antenna elements 19a, 19 / t> of a TACAN antenna a plurality of vertically arranged one above the other cavity resonators 25 with radiating Slots on, wherein the cavity resonators 25 are fed by a common line which is on assigned output of the modulation arrangement is located. As the antenna is not the subject of the present Invention is, it will not be explained further. It should be noted, however, that the in F i g. 2 shown special antenna is for illustration only, and that the modulation arrangement according to the invention is also advantageous in connection with other types of antennas and antennas can be used in which pairs of radiating antenna elements radiate out of phase. The modulation signal source 26 carries each modulation arrangement 17 its own modulation signal pair to, whose two modulation signals are out of phase. The modulation signals of each pair are related to the modulation signals of the other pairs, which expresses the desired radiation characteristic, which is shown, for example, in FIG. 1 is shown.

F i g. 3 shows the circuit of an embodiment of FIG Modulation arrangement. The HF power arrives at the power divider 15 (FIG. 1) to the T-shaped power divider 30, which divides the power into equal power shares on lines 31 and 32. The power divider 30 and the lines 31, 32 can, as shown in FIG is shown, be designed as a stripline. this will be discussed in more detail below. Between the lines 31, 32 and ground or the common Semiconductor elements each have potential for the high frequency and the modulation signal or diodes 34 and 35, which may preferably be silicon PIB diodes.

A periodic modulation signal M (Φ), which can be sinusoidal, is applied to the anode of the diode 35, while a modulation signal Μ (Φ + 180 °), which is in phase opposition to the first modulation signal, is applied to the anode of the diode 34. The blocking capacitors 40, 41 prevent high-frequency components from penetrating into the modulation arrangement. With the fluctuations of the modulation signals applied to the diodes 34 and 35, the currents flowing through these diodes 34 and 35 and thus the effective shunt impedance represented by the diodes 34 and 35 via the lines 31, 32 also fluctuate. These periodic fluctuations in the line impedance, which run out of phase between the lines 31 and 32, cause a corresponding shift in the power distribution between the two lines 31 and 32. Due to the opposing phase of the fluctuations in the effective impedances of the diodes 34 and 35, the sum remains the impedances constant. The same also applies to the sum of the power fed into the lines 31 and 32, which is equal to the sum of the power fed to the power divider 30. It can thus be seen that the RF power on the line 31 fluctuates periodically and in phase opposition to the RF power on the line 32 without power being consumed, if one disregards the small losses which normally occur in the components of the modulation arrangement.
F i g. 4 shows a further embodiment of the modulation arrangement. This embodiment differs from the embodiment described above in that the semiconductor elements or diodes 34 and 35 are each connected in series with the lines 31 and 32. The capacitors 45 and 46 serve as blocking capacitors which prevent the modulation signal from flowing to the RF generator. The HF chokes 48 and 50 represent a path to the ground for the supplied LF signals. However, they prevent the HF signals from flowing away to the ground. The HF Dros.

let 49 and 51 prevent the RF signal from reaching the modulation signal source 26. In this embodiment, the effective series impedances are Diodes 34 and 35 eeeenohasie to each other Edited «V

that the RF power supplied to the pairs of radiating antenna elements fluctuates accordingly gives the same result as in the first embodiment.

F i g. Figures 5 and 6 show a particular practical embodiment of the modulation arrangement according to the present invention Invention. The high-frequency input signals are transmitted via the cable 50 by means of a coaxial connector 51, which can be screwed onto the socket 54. fed in. The shield of the socket 54, which is the ground connection carries is attached to the wall of the metal housing 53, which shields the modulation arrangement. Of the Inner conductor 54a of socket 54 is soldered to the end of T-shaped power splitter 30. The strip lines 31 and 32 take the same power components from the power divider 30 and contain matching sections 56, 57, which in turn end in the widenings 58, 59, to which the diodes 34, 35 on the in the F i g. 3 and 4 are connected in each case shown. The widenings 58, 59 are above the line sections 60, 61 connected to the connection points 65,66.

The middle pins 70a, 71a of the coaxial sockets 70, 71 are with connections 73, 74 and these with the connection points 65.66 soldered. The coaxial jacks 70, 71 are attached to the wall of the housing 53, with the coaxial cables 77,78 providing the modulated output signals the antenna elements via the plugs 79, 80. The power divider 30, the strip lines 31, 32, the widenings 58, 59, the connection points 65, 66 and the connecting lines 60, 61 consist of one electrically highly conductive material deposited on a dielectric substrate 85 by a conductor etching process can be built. The electrical length of the lines from the junction of the power splitter 30 up to each connection point 65, 66 should be the same. In a typical embodiment, the effective electrical length of these two line sections a quarter of the wavelength of the carrier frequency of the transmitted HF signals. The modulation signals for the diodes are applied to the connection pins via lines 90, 91 92, 93 applied, with which the lines are soldered. The connecting pins 92, 93 run through the insulator block 95, which is in the upper part of the housing 53 is arranged, and are connected to the diodes 34, 35 in the FIG. 3 and 4 respectively connected in a removable manner.

For this purpose 3 sheets of drawings

55

M)

65

Claims (3)

Patent claims: 1. Modulation arrangement for amplitude modulation for a radio navigation system, in which the power generated by an HF generator is fed to a pair of radiating antenna elements via a device that divides this power into two equal power components in accordance with a periodic function, the power component on each line in each case is modulated by a modulator having a semiconductor element, characterized in that a modulation signal source (26) is provided for generating two mutually antiphase modulation signals which change the impedances of the semiconductor elements (34, 35) in antiphase so that the sum of the two radiating Antenna elements (19a, i9b) supplied power components remains constant 2. Modulation arrangement according to claim 1, characterized in that as semiconductor elements Diodes (34, 35) are provided, one of which is arranged in a shunt to a line (31, 32) is 3. Modulation arrangement according to claim 1, characterized in that as semiconductor elements Diodes (34, 35) are provided, one of which is arranged in series with a line (31, 32).