DE574954C - Modulation circuit - Google Patents

Description

The invention relates to a modulation circuit tuhg. The known circuits have each has its own particular advantages and disadvantages. For example, in a known Circuit a tube generator or amplifier thereby subjected to the modulation, that the voltage supplied to the anode is changed, this anode voltage change is usually effected by a modulation tube that runs in parallel with the generator and amplifier tube is connected together with an iron-core auto-transformer or a choke coil connected to the anode circuit is common to both tubes. It can also be the modulation tube with a winding of a double-coil iron transformer and the generator or amplifier tubes are connected to the other winding of the transformer, either two or a single common anode voltage source is used.

Circuits of this type are rather complicated and of poor efficiency, when a high percentage modulation is required, especially when it is large Energies. It also has the use of iron cores in the transformers or throttling the tendency to distortion in the wake.

This disadvantage can be avoided by connecting the modulation tubes in series with the generator or amplifier tube and the one through the modulation tube The resistance formed varies by adding the modulation voltages to the grid of the Tube feeds. In such arrangements, referred to as series tube modulation circuits can denote, the change in the internal resistance of the modulation tube has a corresponding change in the the actual anode voltage that is fed to the generator or amplifier tube will. Although such circuits are known and have certain theoretical advantages offer, because of certain technical difficulties they will not be large Used extensively. The modulation tube can either be connected to the high voltage side or to the earthed side of the generator or Amplifier tube are connected. In the former case, the cathode of this generator or amplifier tube and the with it connected resonant circuit must be grounded, however, the source for the negative Grid bias and the source of the low frequency modulation voltages for the full anode voltage can be isolated because the modulation tube is on the high voltage side the generator or amplifier tube. In the latter case, i. H. if the modulation tube with the grounded side connected to the generator or amplifier tube

den, the cathode of this modulation tube can be grounded and the various Input circuits must be arranged in an expedient manner, but now the oscillation circuit of the generator or amplifier tube at high voltage, causing trouble due to leakage leads.

These disadvantages are intended to be eliminated by the present invention.

According to the invention, in a series modulation circuit, in which the modulation tube in series with the low voltage side of a high frequency generator or amplifier tube is switched on, the output circuit of this latter tube is thus through capacitors connected by such a value that this oscillation circuit is connected to earth can be connected without affecting the functioning of the transmitter as a whole. These Coupling capacitors should have a high reactance and for the modulation frequencies for the high frequencies have a low reactance, whereupon the oscillation circuit can then be connected to earth.

An embodiment of the invention is shown in circuitry in the drawing.

The transmitter contains an amplifier tube V ₁ to which the high-frequency oscillations between the grid and anode are fed _{via a coil L 3.} The grid circle of this tube contains the grid _{coil L 5} and the grid resistor R ₁ in a known manner. The grid and cathode are _{coupled via the capacitors C 4} and C _s to the input circuit L ₂ , C ₆ , the inductance L _{2 of} which is formed by the secondary winding of a transformer, the primary winding of which is the coil L ₃ . The anode is connected to the anode voltage source _{via a choke L 4} and connected to one end of the output _{circuit C 3} , L _{3 via a capacitor C 1} , while the cathode is connected to a tap point T on the coil L _{1 via a similar capacitor C 2} . The end of the circuit L ₁ , C ₈ further away from the capacitor C ₁ is coupled to the grid of the tube via a neutro-capacitor C _8. This capacitor and the tapping point T are chosen so that the internal capacitance is neutralized. Of course, you can also choose any other Neutro circuit.

The output circuit is coupled to the useful circuit, for example with one or more tubes of higher energy or, as shown, with an antenna A ₁ which, like the tapping point T, is grounded. The connection point of grid _{choke L 5} and grid resistor R _x can, if necessary, be connected to the cathode end of the grid resistor via the usual diversion capacitor, this latter point also being connected to the anode of the modulation tube V _2; the cathode of this tube is connected to earth and to the negative terminal of the anode voltage source, while the modulation voltages are applied to its grid. This feed takes place via the capacitor C ₉ , the grid side of which is also connected to the cathode of the modulation tube through a series connection of a resistor R ₃ and a bias battery JS ₁ .

The cathode of the amplifier tube is heated in a known manner by electrical energy which is supplied via an iron core transformer TR from a common low-frequency alternating current source. The ends of the secondary winding of this transformer are connected to the ends of the cathode, which is bridged by a resistor R ₂ , the center point of which is connected to one side of the capacitor C _{2 in} order to compensate for the sound modulation from the heating power source. Naturally, the heating can also take place from an isolated direct current source or by indirect means.

However, if the cathode, as in the embodiment, via a transformer is heated, this must be designed so that between its primary and secondary winding and the smallest possible capacitance exists between the secondary winding and the core, thus high modulation frequencies cannot be diverted to earth.

This circuit achieves the best results with regard to the depth of the permissible modulation, when the grid voltage applied to the modulation tube is such that the voltage drop at the modulation tube in the static and unmodulated state is somewhat larger than that at the amplifier tube. The capacitors that couple the anode and cathode of the amplifier tube with the output circuit should be of such value that their reactance at the high frequencies is relatively small and at the highest Modulation frequencies is large. If this condition is met, the output circuit can be grounded without affecting the functioning of the transmitter and without noticeable Distortion over the range of frequencies normally required for high quality speech and music.

If the cathode of the amplifier tube is as described via a transformer is heated and if this transformer of sufficiently high capacity between its windings, this capacitance can be the coupling capacitor between cathode

and form an output circuit, which eliminates the need for a special capacitor. However, it is more expedient to use the circuit described and to choose the capacitance between the turns of the transformer as small as possible. Instead of coupling the cathode of the amplifier tube through the capacitor C ₂ - , it can also be connected directly to the tuned circuit

ίο be connected, then in the line a capacitor is connected between this circuit and earth.

In some cases you can use the capacitors C ₄ , C ₅ , which the input circuit L ₂ , C ₆

iS couple with the grid circle of F ₁ , omit it and connect this circle directly to the grid and cathode point.

Claims (6)

Patent claims: «Ο i. ' Modulation circuit in which the Modulation tube (F ₂ ) is connected in series to the low-voltage side of a high-frequency generator or amplifier tube (V ₁ ) , characterized in that as the output circuit of the generator or Amplifier tube is connected to the low voltage side via capacitors according to the selected capacitance. 2. A circuit according to claim i, characterized in that the output _{resonant circuit is connected to the tube (F 1} ) via capacitors which are of high reactance for modulation frequencies and of low reactance for high frequencies. 3. A circuit according to claim 1 and 2, characterized in that the cathode of the tube (V ₁ ) is connected to a tap point (T) at the inductance (L ₁ ) of the output circuit, one end of which via a neutro capacitor (C ₈ ) the grid of this tube (V ₁ ) is connected. Circuit according to Claim 3, characterized in that the cathode of the tube (F ₁ ) is heated via an iron core transformer (TR) and bridged by a resistor (R ₂ ) , the center of which is connected to the tapping point (T) _{via a capacitor (C 2).} connected is. . 5. A circuit according to claim 4, characterized in that the heating transformer (TR) between its primary and secondary winding and between the secondary winding and the core has the lowest possible capacitance for the purpose of preventing high modulation frequencies from being exceeded to earth. 6. A circuit according to claim 4, characterized in that the coupling capacitor (C ₂ ) in the line between the cathode and the tapping point (T) is replaced by the winding capacitance of the transformer (TR) . 1 sheet of drawings ium im. okprints in the heichsdrickekui