DE728583C - Short wave vibration generator - Google Patents

Description

Shortwave Vibration Generators The invention relates to circuits for push-pull vibration generators, especially in the area of centimeter and decimeter waves, through which not only a better stability, but also a better efficiency achieved and also enables a more favorable coupling of a subsequent stage will.

On the one hand, it is known for a vibration generator consisting of a tube to arrange the tube in the tension belly of a two-wire system and this on both The sides of the tube can be adjusted by sliding capacitor bridges. It is on the other hand Known for push-pull transmitters, both grids and both anodes are each connected to a two-wire line to lay and vote these separately or the anode and the grid of the one Tube with the anode and the grid of the second tube via a two-wire system to connect and to adjust this by its length in a suitable manner. There are also known arrangements in which two tubes oscillating in push-pull in one Vierwrahtlechersystein are arranged. The coordination between the made the same electrodes of the tubes, which are arranged in a Huth-Kuehne circuit are. Since with such an arrangement the tuning bridges are not exactly in the voltage node can lie, because namely phase shifts between the two bridge points occur, the two Lecher systems cannot oscillate in exactly the opposite direction. Common-mode components or asymmetrical components occur that affect the whole system.

According to the invention, these disadvantages are eliminated in that the tuning with the help of tuning bridges within the grid and anode bars formed Lechersysteme takes place, while the coupling to the by the bars and / or anode rods formed Lechersystem is made. To the FIG. 1 shows a schematic exemplary embodiment for a better explanation of the invention in a three-dimensional representation and FIG. 2 shows a cross section through the system. Fig. 3 also illustrates in a spatial representation the coupling of two separate ones Tube stages and Fig. 4 a schematic circuit diagram for: Modulation of the device according to FIG. 3. The reference numerals are the same for the same parts in all the figures.

In Fig. I, R1 with the two-wire system i, i and 2, 2 and R @ with the two-wire system 3, 3 and 4, 4 mean two oscillators connected in push-pull, which are separated once together by the short-circuit bridge with the capacitor 5 and a second time be matched by the short-circuit bridges with the capacitors 6 and 7. This separate adjustment 6, 7 makes it possible to compensate for small inequalities between the two tubes. The letters A and G are designations for the anode and grid of the tubes and for the feeds of the corresponding voltages.

The push-pull arrangements described now have the following mode of operation: Both tubes have an independent double wire system between their anode and their grid, which is tuned to the wavelength. Both systems are interrelated by the common Capacity 5 capacitive and permanently coupled inductively due to the spatial arrangement, thereby a perfect mutual entrainment and thus both a defined Vibration state as well as a good frequency stability is achieved. The fixed one However, coupling between the two systems also results in significantly lower radiation losses, so that a more favorable level of control and therefore also a significantly better one Efficiency of the vibration generator is achieved. In the vibrating state can one understands the four-wire system as a four-fold double-wire system, there next to the 2 oscillation circles formed by the two-wire systems i, 2 and 3, 4 The double-wire systems i, 3 and 2, 4 also act as oscillating circles. This is illustrated by Fig. 2, in which for a particular vibration state the sign of the oscillation at points 8, 9, io, i = _ is shown.

The transmitter arrangement described in FIG. 1 now allows, according to the invention, one or two push-pull tube stages to be coupled without DC voltage, as is shown schematically in FIG. 3. The two-wire lines i, 3 and 2, 4 are extended beyond the points 18, i9, 2o, 21, at which the capacitive short-circuit bridges 6, 7 are, and the tubes R3, R4, R, and R6 in one of the wavelengths corresponding Distance arranged. On the anode side, further double lines 12 and 13 with short-circuit bridges 14 and 15 are used for: I #, tuning to the wavelength. Here, the high-frequency energy is then taken off in the usual way, either directly or with the addition of further stages. For better matching of the coupled push-pull stages, variable variable capacitors 16 and 17 can be arranged which, depending on the point at which they are located, require different capacitance sizes. In the same way, the voltage nodes can be shifted precisely to the points 18, ig, 2o, 21 through this, so that the geometric inequalities in the length of the Doppeldrahtsy caused by the tube capacities can be compensated for.

This DC voltage-free coupling of further push-pull stages on the vibration generator has the great advantage that it is completely symmetrical is loaded and the reactions that occur with other circuits can be largely reduced. It is also achieved that in this Coupling without the use of any lossy intermediate links the greatest possible tension is transmitted to the grids of the following stage. It can however, in some cases a different type of coupling also prove to be beneficial (Capacitors, inductors) to be used if one is not looking for the most optimal coupling Value.

4 now shows a schematic circuit example for the modulation of an arrangement according to FIG. 3. The oscillation generator stages R1, R., whose grid bias is generated by a cathode resistor, operate on the grid side on the one modulation stage R3, R4, in whose grid cathode line the modulation is inserted . In this case, too, the grid bias can be generated by one of the known cathode resistor arrangements, but it has proven to be more advantageous to perform this with a bias battery in order to obtain a grid potential that is independent of the modulation voltage. As can be seen from the circuit, the grids of both tube stages are at ground potential, while their cathodes are at another potential different from ground, which can be generated either by cathode resistance or an additional battery. The lattice cathode circuits of both tube stages are therefore separated in terms of DC voltage, so that one can speak of a DC voltage-free coupling here. The second modulation stage RS and R6 is controlled from the anode side of the oscillator R1 and R2. The modulation can again be carried out in the grid cathode line. In order to enable a DC voltage-free Ankopp-Jung with this, an independent, ungrounded voltage device must be used, so that the same advantages are available. Another known modulation method can also be used to modulate the two tube stages Rs, R4 and R5, R6, and the advantages mentioned will always be present if the circuit is then modified in accordance with the features described.

The great advantage of this invention, two completely separate tube stages to be coupled symmetrically and as far as possible without any reaction to a vibration generator, especially when it comes to these two levels to connect separate, single-wave and phase-locked oscillating transmitting devices and to transmit with these two separate modulations (e.g. using an intermediate frequency modulation at one stage). Because with this there is the possibility to use the whole straight part of the oscillation characteristic for each modulation.

With other methods in which two separate modulations (also when using an intermediate frequency) transmitted by a transmitting device are, very often distortions arise when the sum of the modulation amplitudes of both parts goes beyond the straight part of the visual swing characteristic, and inevitably If one part of the modulation is distorted, the other part is also distorted a. It is precisely these errors that are avoided in the method according to the invention, since Both stages are completely independent in terms of modulation and a distortion of the Modulation in one level does not affect that in the other level in any way can.

To increase the high frequency energy you can use several tubes parallel as well as several push-pull stages can be switched one behind the other: At In the latter case, the four-wire system must be lengthened by half the wavelengths how push-pull stages should be used, so that all stages are each in a tension lie.

Claims (1)

PATENT CLAIMS: i. Arrangement for generating vibrations from short or Ultra-short waves with the help of two tubes oscillating in push-pull that are in one Four-wire system are arranged, characterized in that the vote with With the help of tuning bridges within the Lecher systems formed by grids and anode bars takes place while the coupling to the through the bars and / or anode bars formed Lechersystem is made. a. Arrangement according to claim i, characterized in that that the Lechersystems of the two tubes share a coupling capacitor (5) own. 3. Arrangement according to claim i and a, characterized in that in the Vibration generator stage several tubes are connected in parallel. q .. arrangement according to claim i to 3, characterized in that the four-wire system for increasing the high frequency energy by so much half a wave. length is lengthened, as in Series connected push-pull stages are to be arranged. 5. Arrangement according to claim i to q., characterized in that the grid of a push-pull stage is galvanic connected without direct voltage to the grids of the push-pull generator are. 6. Arrangement according to claim i to q., Characterized in that the grating a coupled push-pull stage with the anodes of the push-pull oscillator are galvanically connected without direct voltage.