DE862780C - Circuit arrangement with slope-controlled susceptance values - Google Patents

Description

Circuit arrangement with slope-controlled susceptance values In the High-frequency technology often requires adjustable apparent resistances, such. B. for tuning bridges in measuring devices, for tuning oscillation circuits in receivers or also in transmitters, for example when transmitting a measured value by specific choice of the transmission frequency or to periodically change a transmission frequency for various measuring purposes and for other purposes more.

Slope-controlled susceptance values are advantageously used for this purpose, between the anode and cathode of a tube with high internal resistance, in particular a screen grid tube. Such circuits in which between Anode and grid a reactance inductive or capacitive character and an ohmic resistor is arranged between the grid and the cathode or vice versa, are based on a voltage division between anode and and grid tension.

The range over which the susceptance value can be changed is limited, especially when used for frequency modulation circuits, as there to avoid larger distortion factors, only a relatively small range of steepnesses is used can be. The object of the invention is to enlarge the range of variability controlled susceptibility values.

An enlargement of the variability range of a controlled susceptance value can be achieved according to the invention by a two-stage or multi-stage arrangement in the following way. Reference is made to the principle diagram in FIG. The susceptance jY 'represented by a conventional control circuit A is used as the BI inductance of the voltage divider of a second control circuit B, in which, for example, the slope is assumed to be constant. From the resistors R ,. and R2, the between anode and grid or grid and cathode of the tube V1, the z. B. a screen grid tube, one is a reactance while the other is an ohmic resistor. The control voltage is applied at i, 2. If the resistance between the grid and the cathode of the tube V2, which is also formed, for example, by a screen grid tube, is an ohmic resistance R and the steepness of the tube V2 in B is S and the practically necessary requirement is met that the one between the grid and anode Resistance to R is large, the susceptance iY appearing at the output of the second tube is "given by IY" = (i + RS) Y ', so that the amplification factor is the size can view. In practice, gain factors above io can easily be obtained here. This results in the following important advantage: If the amplifier tube itself can be assumed to have a constant slope, the operating point can be placed in the straight-line area of high slope, ie so that this tube provides a low distortion factor. The actual control tube, however, only needs to be controlled by the amplification factor of the second tube, which means that the total distortion factor can be reduced considerably.

An embodiment of one of the possible circuits using the basic diagram of FIG. i is shown in FIG. With this arrangement is in the control circuit A between the anode and the grid of the tube resistor formed by a capacitance 0, while the one between the grid and the cathode Resistance is formed by an ohmic resistance R. In the second control circuit B is the resistance between the grid and the cathode due to an ohmic resistance R2 formed. In. the anode power supply,. are chokes D, _, D2 for locking intended. To the other switching elements shown, which are not designated in any more detail will not be discussed further here, since it is not necessary for an understanding of the invention appears. In the exemplary embodiment, there is therefore a slope-controlled capacitance shown, in which by a multi-level arrangement an enlargement of the changeability range has been achieved.

So far, a constant slope has been assumed for the second tax level. If you control the steepness of the second control level in the same rhythm as that of the first, this already results in a doubling of the frequency deviation. One Even more extensive reinforcement can be achieved according to a further invention by that the mean output conductance of the first tube circuit by a opposite equal compensated, so that only the changes in the susceptance of the first tube circuit can be amplified in the next control level. Through this the full reinforcement comes into play. Gains of 3 (i -f- RS). .

In the case of a slope-controlled capacitance, as shown in FIG. 3, in which a capacitance C is arranged in the control circuit A between the anode and grid of the tube and an ohmic resistance R is arranged between grid and cathode, the dashed average output capacitance C is through a coil to compensate. In the second control circuit B, only the change in capacitance then comes into play between the anode and the grid.

Both tube circuits can be controlled with the same control voltage will. However, the control of the second tube circuit is particularly advantageous by a voltage distorted in such a way that the one arising in the first tube circuit Harmonic distortion is canceled.

Even with the multi-stage arrangement according to the invention, the known measurements of resistance combinations between anode and grid or Grid and cathode are used to create approximately loss-free apparent resistances to achieve.

Claims (6)

PATENT CLAIMS: i. Circuit arrangement with slope-controlled Susceptance values using a tube of high internal resistance in which a reactance between the anode and the grid and between the grid and the cathode Ohmic resistance is connected, or vice versa, especially for frequency modulation circuits, characterized in that the susceptance value resulting between anode and cathode as susceptance between anode and grid or grid and cathode of another similar tube circuit is used. 2. Arrangement according to claim i, characterized in that that the slope of the further tube circuit is constant. 3. Arrangement according to claim i, characterized in that the steepness of the further tube circuit is the same Rhythm like that of the first is controlled. q .. Arrangement according to claim 3, characterized characterized in that the mean output conductance of the first tube circuit is compensated by an opposite equal. 5. Arrangement according to claim 3 or q., Characterized in that both tube circuits with the same Control voltage can be controlled. 6. Arrangement according to claim 3 or q., Characterized in that that the further tube circuit is controlled by such a distorted voltage, that the distortion factor occurring in the first tube circuit is canceled.