DE583863C - Telegraphy circuit for keying multi-level high-frequency transmitters - Google Patents

Description

The invention relates to a circuit for keying multi-stage high-frequency transmitters, for example for the purposes of wireless telegraphy and image transmission. In broadcast with multiple cascades it is difficult to achieve a high keying speed. this stems from the fact that the starting circles of the individual stages have a certain oscillation persistence, so that after Stop touching the vibrations for a certain period of time, which depends on the time constant of the relevant output circuit. During this Period of time these vibrations are fed to the grid of the next tube, where the same process is repeated. This gradual swing has character extensions as a result, and this disadvantage is intended to be eliminated by the present invention.

According to the invention, the signaling is carried out simultaneously in two cascades of the transmitter, which are separated by one or more intermediate stages. If the tactile impulses the transmitter in the form of low frequency AC signals are supplied and a screening of the low frequency carrier is desired are on known means have been used to smooth the gain obtained by rectification DC pulses without the use of filter circles, the transient processes of which would limit the scanning speed, to achieve.

An example of the application of the invention to a transmission device for wireless telegraphy is shown on the drawing.

The vibrations generated by the vibration generator 1 are through the Cascade amplifier 2 to 8 amplified and fed to the antenna 9. It's just the circles represented by two such amplifiers 3 and 7 controlled by a key circuit shown in the lower part of the drawing. Any of these amplifiers 3 and 7 has an output circuit 10, in which the vibrations continue to sound, after the amplifier is disabled. During this time they will be through amplifies the amplifiers 4, 5 and 6, which remain permanently in the operating state and whose output circles show a reverberation in a similar way. Accordingly, the grows Period over which the vibrations in

The output of the last amplifier will continue to sound after the tube 3 has been disabled, with the number of amplifiers that are maintained in the operating state. If, however, one of the latter stages of the cascade is keyed in synchronism with the previous amplifier, satisfactory operation can be obtained at very high keying speeds.
The probe circuit of the transmitter consists of several tubes 11, 12, 13, 14 and the two direct current amplifiers 16 and 17. The alternating current, which is interrupted at the scanning speed, is fed to the grids of the '5 rectifiers 11 to 14 through a transformer 15, the primary winding of which is connected to a source of AC strobe pulses. The secondary winding of this transformer is connected on the one hand to the grids of the tubes 11 and 13 via the inductances 18 and 19 and on the other hand to the grids of the tubes 12 and 14 via the capacitors 20 and 21. The vibrations applied to the grating of FIG. 13 are shifted in phase by 180 ° with respect to the vibrations applied to the grating of FIG. 11; the same phase shift applies to tubes 12 and 14. On the other hand, there is a phase shift of 90 ⁰ between tubes 11 and 12 or 13 and 14. The anode circuits of 11 and 12 or 13, 14 are connected in parallel and are fed by the direct current source 23 via a resistor 22. The purpose of this phase shift in the grid circles of the tubes 11 to 14 is to generate a relatively smoothed rectified EMF at the resistor 22, the size of which depends on the alternating current supplied via the transformer 15, without special smoothing devices being provided in the output of these tubes will need. This is based on the fact that the single-phase alternating current characters, which are fed to the primary side of the transformer 15, are converted into polyphase alternating currents before being rectified, so that the rectified current has a lower ripple. The grid and cathode of the tubes 16 and 17 are connected in parallel to the resistor 22, so that the impedance between the anode and cathode of these tubes is regulated in accordance with the voltage across this resistor 22. The anode circuit of 16 contains a resistor 24 and a voltage source 25, both parts of which are also located in the anode circuit of the amplifier 3. The anode circuit of FIG. 17 contains a direct current source 26 and resistor 27, the latter also lying in a circle which runs from the grid of the amplifier 7 via a choke coil 28 and the resistor 27 to the cathode of the amplifier 7.

The mode of action is as follows. Usually this is the grid of the tubes 16 and 17 applied voltage so that these tubes of relatively lower Impedance are and consequently a relatively strong current in both anode circuits flows. This current flowing in the anode circuit of 16 causes a Voltage drop in resistor 24, which reduces the EMF between the cathode and anode of 3 so much that this tube is ineffective will. At the same time, a negative voltage is applied to the grid of 7 due to the strong current flowing in resistor 27, which makes this amplifier ineffective. As a result, the generator 1 and the amplifiers 2, 4, 5, 6 and 8 are kept in readiness for work, no vibrations through the system and broadcast from the antenna 9.

If there is alternating current in the transformer 15, the amplifier is switched to each 11, 12, 13 and 14 an increase in the Electricity caused. This current flowing in the resistor 22 causes a negative current Bias voltage applied to the grids of the tubes 16 and 17 so that these Tubes get a high impedance. The high impedance of the tube 16 reduces the Current in resistor 24 and thus the voltage drop across this resistor, whereby the anode voltage of 3 is increased so that this amplifier becomes effective again. At the same time reduces the increased impedance of 17 the negative voltage across resistor 27, whereby the The grid of 7 is preloaded just enough for this to work effectively Tube is enough. Since all amplifiers are now in working condition, the Generator 1 generated vibrations successively amplified by amplifiers 2 to 8 and radiated from the antenna 9. Of course, if necessary, the first stage, which is the vibration generator 1, or level 2 can be keyed at the same time as the last amplifier level. The mode of operation is better, however, if the vibration generator swings through continuously and only the keying takes place in the amplifier stages. So that the one generated by the exciter 1 Frequency is not influenced by the keying, it is also appropriate that at least an unsampled gain stage between the vibrator and the first gated gain level.

583868

The output circuits of the power amplifier stage are connected to the antenna 9. coupled that represents a resonant circuit with high resistance. As a result, they sound Vibrations in the power amplifier stage quickly decrease. For this reason it is useful moderate to leave this stage in permanent operational readiness while the previous one Level is keyed.

Claims (2)

Patent claims: i. Telegraphy circuit for keying multi-level high-frequency transmitters, thereby characterized in that at least two are unswitched by one or more Steps separated steps are keyed. 2. Circuit according to claim 1, characterized in that in per se known Way in the grid circles of the rectifier tubes (11, 12, 13, 14), which for Rectification of the alternating current keys are used, inductances (18, 19) and Capacities (20, 21) are switched on by this phase control without application comparatively smoothed direct current impulses at the im Anode circuits of the rectifier (11 to 14) to obtain the resistor (22) lying. 1 sheet of drawings