DE720056C - Circuit arrangement for achieving a constant high-frequency amplitude in multi-stage high-frequency transmitter amplifiers - Google Patents

Description

Circuit arrangement for achieving a constant high frequency amplitude with multi-stage high-frequency transmitter amplifiers In high-frequency transmitters with control and amplifier stages in which the transmission waves can be selected in a larger range are adjustable, difficulties arise in certain cases in that the control voltages delivered to the following stages at different wavelengths are unequal. This phenomenon is dependent on the respective. Transmitter frequency dependent resonance resistance of the resonant circuits in the tube stages.

It has already been suggested in telephony transmitters where one modulated high frequency should be amplified in several stages without distortion, the Anode resonant circuits through ohmic resistances connected in parallel, their size against the resonance resistance of the oscillating circuits is small, to dampen so that the total resistance is essentially independent of frequency. This creates a large power loss, which is compensated for by increasing the number of amplifier stages must become.

There are also special, automatically acting pre-tensioning regulations became known, but in which complicated rule arrangements. are needed.

According to the present invention, these disadvantages are avoided by that parallel to each resonance circuit serving for the coupling is a series circuit an ohmic with a reactance and that with frequency adjustment of the Resonance circles through a variable self-induction of the reactance inductively and is capacitive when the frequency is set by a capacitance.

It is thereby achieved that a frequency-dependent additional attenuation is present is, through which a load balancing is achieved with the lowest possible self-consumption will. without the need for complicated control arrangements. Depending on the natural oscillation of the circle by changing the self-induction at a fixed capacity or by Change in the capacity is set at fixed self-induction, is dem Additional ohmic resistance is preceded by an inductive or capacitive reactance.

The figures show an exemplary embodiment of the invention Circuit arrangement and a graph to explain the effect. In fig. i is a tube i of a transmitter stage with a tube 2 of the next transmitter stage coupled via a resonance circuit 3 located in the anode circuit of the tube i, which consists of a capacity q. and one to adjust the natural oscillation variable Inductance 5 exists. The oscillating circuit has an ohmic damping resistance 6. To achieve a constant amplitude of the control voltage for the grid of the Tube 2 is connected to the oscillating circuit 3 via an inductance 7 as a reactance an ohmic resistor 3 connected in parallel.

The reactance 7 represents a higher resistance for shorter waves so that a smaller current flows in the ohmic resistance S than at -longer waves. and thus only an insignificant decrease in the resonance resistance entry. With longer waves, however, a larger part of the oscillating ice current flows through the reactance 7 and en additional resistance ä, so that the resonance resistance of the entire coupling member is reduced more. Fig. 2 shows the course of the resonance resistance of the coupling member, namely curve i the course without additional resistance. The resonance resistance increases from the shorter wave Ac, after the longest wave i.1 of the area increases sharply. The curve: z shows the resonance resistance of the entire coupling link (circle 3 and additional link and S), which is practically over the wave range 2a to A., is constant. So for this curve is the amplitude the control voltage delivered to the grid of the tube 2 is constant. The one in the curve The dependence of the resonance resistance on the wavelength shown in FIG. 2 was for example achieved in that the reactance 7 is approximately five times the value of the initial self-induction value the variable inductance 5 was measured.

Claims (1)

PATt: NTANsrRUGH: Circuit arrangement to achieve a constant high-frequency amplitude with multi-stage high-frequency: n7sender amplifiers in which the tube stages are coupled via resonance circuits and the transmitter frequency can be adjusted over a larger range by changing the self-induction or capacitance of the resonance circuits, characterized in that parallel to each resonance circuit serving for coupling there is a series connection of an ohmic with a reactance and that when the frequency of the resonance circuits is set by a variable self-induction the reactance is inductive and when the frequency is set by a capacitance it is capacitive.