DE754302C - Arrangement for overlay receiver to regulate the gain by means of a rectified control voltage derived from the oscillator - Google Patents

Description

. Arrangement for superimposed receivers to regulate the gain by means of an oscillator-derived reference voltage. The invention refers to superheterodyne receivers whose tuning range is outside the broadcast wave range still covers a large part of the shortwave range. The purpose of the invention is the compensation of gain differences in the different frequency ranges, caused by an uneven oscillation amplitude of the oscillator on the individual Areas are caused. In a superheterodyne receiver, the transposition gain is largely determined by the way the oscillator works. The transposition gain is defined as the ratio of the intermediate frequency voltage at the output of the modulator to the voltage the received high frequency at the input of the modulator. When the vibration amplitude of the oscillator drops, as it does at extremely high frequencies usually is the case, the amplitude becomes the intermediate frequency and thus the transposition gain also sink.

According to the invention is in an arrangement for heterodyne receivers to regulate the gain by means of a rectified one derived from the oscillator Control voltage the control voltage acting on an amplifier tube or the mixer tube dimensioned so that the influence of the change in the oscillator amplitude on the gain of the overlay receiver is canceled. The gain then increases when the oscillator amplitude goes down and the overall gain remains pretty much constant.

A bias voltage that changes with the oscillator amplitude becomes obtained by a blocking capacitor shunt resistor combination with a grid of the oscillator connects. One can derive the bias voltage on the control electrode from a or more high frequency or intermediate frequency amplifier tubes or the mixer tube Take effect to make the gain inverse to the amplitude of the oscillator voltages to regulate. If you feed back the input and output circuits of a modulator tube, this is how the control voltage applied to the modulator and derived from the oscillator grid can be used serve to regulate the level of feedback. When using different tubes for the oscillator and the modulator, the control voltage is sent to the modulator control grid created. In the case of using a single multiple grid tube as a combined one Oscillator modulator, the inner three-electrode part including the cathode as an oscillator and the outer four-electrode part including the anode as a modulator works, the emission of a virtual cathode between the oscillator and the modulator part is automatically regulated in reverse to the bias on the oscillator grid. The conductance of the outer four-electrode part and thus the gain changes with the emission of the virtual cathode. If the oscillator amplitude is large, so is the average negative bias coming from the oscillator, also great. This results in a relatively low conductance in the preloaded. Amplifier or modulator elements and a correspondingly reduced gain. Conversely, if the oscillation amplitude is low, the negative bias voltage is also the same low and the conductance of the prestressed elements is correspondingly high, which is a increased gain is associated. When you consider the individual parts of the arrangement expediently dimensioned so you can adjust the gain up to any desired Compensate for the gain differences caused by the oscillator.

In the following the drawings are explained: In Fig. I contains the receiver shown has a level of tuned high frequency gain in Cascade connection with the tube L'1, on which the oscillator-Jlodtllator-Röllre h, follows, its modulated power to a stage of intermediate frequency gain with the tube I'3. The tube l'4 works as a combined detector and low frequency amplifiers; after further amplification through the tube V5 becomes transmit the final power to a loudspeaker L. The system is different from the usual Rectifier-filter combination B is supplied with energy to reduce the AC mains voltage to convert into rectified voltage that is taken from the voltage divider D and is fed via lines E to the individual tubes.

The antenna circuit i is connected to the input of the tube L'1 through a Transformer T1 coupled, which has a primary coil P1 and a secondary coil S1, matched by a variable capacitor C1. A similarly tuned transformer coupling P2, S2 is used between the tubes I% 1 and l'2. The secondary coil S1 of the Transformer T1 and the primary coil P2 and the secondary coil S2 of the transformer T2 are tapped at intermediate points that correspond to the corresponding rotary switches R1, R2 and R3 lead to set the system so that it is over consecutive Frequency bands of the all-wave range works. The throttle switch arms are one One-button operation U1 summarized for simultaneous setting of all circuit parts to enable. The tuning capacitors Cl and C are also available for one-button operation U2 for the simultaneous tuning of the circles through continuous gradation over each Frequency band combined. The intermediate taps of the coils Si and S2 are through the adjustable block capacitors C4 and C "are connected to earth to get the through One-button operation to bring coordinated circles in sync with each other Tubes 1'2, i'3 and l'4 are cascaded to the intermediate frequency by means of the transformers T5 and T6 coupled by the adjustable capacitors C5 and C, tuned will. The circuit of the detector I'4, the low-frequency amplifier L'- and of the loudspeaker L can be seen from the drawing. The oscillator-modulator tube T12 contains a cathode K, an anode A and several in a single vacuum vessel Grids in between, referred to in this specification as the inner or oscillator control grid q., the oscillator anode 5, the inner screen grid 6, the input control grid 7 and the outer screen grid 8 may be designated.

The secondary coil S2 has its end leading to earth voltage connected to the input control grid 7, while the other end of the coil S2 is grounded through the capacitor 9 for high frequency oscillations. The cathode K the tube T12 is for receive and oscillator frequencies through the capacitor C7 grounded, which bridges the bias resistor ro.

The inner triode part of the tube T12, the cathode K and the grid q. and 5, generated by means of associated impedances external to the tube lie, oscillations of the superposition frequency. The grids are q. and 5 over interconnected coils P4 and P5 connected to earth. The cathode K is also as already mentioned, grounded for the auxiliary frequency through the capacitor C7. the in this way from the grids q. and 5 circles leading to cathode K via earth form due to the coupling between the coils P4 and P5, which are suitable for this purpose are polarized, a feedback. This feedback is used to generate self-excited vibrations to generate for the overlay. A tuning capacitor is in parallel with coils P5 C9 arranged.

Just like transformers T1 and T2 are also coils P4 and P5 connected from intermediate points with associated rotary switches R4 and R5, the to the one-button operation TI, are summarized to the oscillator frequency dem to adapt the respective receiving band to which the receiver through the positions the switch R1, R2 and R "is set. The blocking capacitors C, and Cio are connected to taps of the coil P5 and are used to adjust the associated Oscillating circuits in relation to the other oscillating circuits of the circuit.

Changes in the amplitude of the auxiliary oscillations occur in the coils P4 and P5 when changing the frequency. The increases within a given frequency band Vibration amplitude with the frequency on because of the increase in the induction effect between coils P4 and P5. If, on the other hand, the working range of a lower is moved to a higher frequency band, the - average oscillation amplitude generally lower according to the changed inductances of the coils P4 and P5. In the drawing it is indicated that for the higher frequency ranges Coil parts are used between the taps with an ever decreasing number of turns will.

In order to develop the required control voltage, it is necessary to work on the inside Oscillator grid q. a blocking capacitor C12 and one connected to the cathode K Resistor R connected. When the oscillation amplitude of the oscillator is large, so the average negative bias on the grid becomes q. also big, the emission of the virtual cathode formed between the oscillator and the modulator becomes low, and thus the conductance of the outer tetrode part of the decreases Tube. Conversely, if the oscillator amplitude is low, the bias voltage on the grid is increased q. only slightly negative, and the conductance of the outer tetrode part of the tube increases at.

Fig. Z shows the invention applied to a receiver in which a separate modulator tube T15 and an oscillator tube T17 are used. The incoming characters are applied to the input control grid G6 of the modulator via the transformer T2, which has a secondary coil S2 which is tuned to the receiving frequency by C2, the modulated output power of which is fed to the further stages of the circuit by the tuned transformer T5. This output power of the tube V6 is superimposed by the capacitors C11 and C7, which are connected between the anode As and the earth, the oscillator frequency on the way via the coil P6 between the cathode and earth. In the oscillator circuit, a matched impedance, which consists of the coil P [with the shunted variable capacitor C9], is connected between the grid G7 and the earthed cathode K7 of the tube T17. The anode A7 is grounded via a coil P5 and a capacitor 16. The coil P5 is coupled to the coil P4 in such a way that it causes self-excited oscillations at a frequency which is determined by the position of the capacitor C9. The vibrations are fed to the modulator tube II via a connection 17 which contains the coil P5 which is coupled to the coils P4 and P5.

The blocking capacitor C12 in front of the grid G7 and the shunt resistor R between grid and cathode of tube T17 create one of the oscillator amplitude dependent bias voltage, which via a connection 18 to the input control grid G6 of the Modulator is directed. This connection contains series resistors R2 and R3, their intermediate point grounded through a shunt capacitor C15 is so as to flatten pulsating components of the preload.

When the arrangement of FIG. 2 is in operation, when increasing Vibration amplitude an increasing bias voltage from the oscillator grid over the conductor 18 to the modulator grating, which increases the internal conductance and the feedback gain of the modulated characters decreases. The reverse of this chain of reactions will be caused by a reduction in the oscillation amplitude.

3 shows a graph of the effect on the exercise gain by changing the capacitance of the capacitor C7, the capacitor C11 being fixed remains, except for the necessary re-voting. By choosing a specific The capacitance value K for this capacitor becomes a fairly constant transposition gain in the case of large fluctuations in the auxiliary oscillation in the order of magnitude of 1 to 8 volts delivered. It can be seen from the graph that the setting of the capacitor C7, however, is quite critical. He shouldn't be more than plus or minus ioo / o of the value K fluctuate. When a capacity of nearly 0.811 is used, the feedback ring tends to occur with small amplitudes of the oscillator to generate vibrations themselves. On the other hand, if the capacitance K is doubled, so the transposition gain goes noticeably with small amplitudes of the oscillator return. The curve C7 = oo gives the relationship between the oscillator amplitude and the transposition gain under the condition that the feedback is omitted will.

Fig. D. shows capacitance values - for the same C7, as in FIG. 3 the decrease in the feedback gain of the modulator as the voltage amplitude increases of the oscillator.

Fig. 5 shows the invention applied to a receiver in which a multigrid tube h, as a combined oscillator and not a feedback one Modulator is used and in which the gain control on the intermediate frequency amplifier tube 1'. is made. High frequency vibrations are caused by the transformer T2, which has a secondary coil S, with capacitor C2 connected in parallel, to the entrance grid; of the modulator part of the tube 1'8; the modulated power is applied to the Z intermediate frequency amplifier tube h. transmitted via the tuned transformer 75.

In the oscillator circuit is a tuned circuit that comes from the coil Pd, the fixed capacitor C, and the variable capacitor C9 exist between grids q. and cathode K of the tube L ', connected across the shunt capacitor C7. the Oscillator anode 5 is also connected to cathode K via capacitor i6, coil P ,, and shunt capacitor C7 connected. Coil P5 is inductively coupled to coil P4, so that self-excited vibrations arise from a frequency that is determined by the position of the capacitor C9 is determined. The vibrations are used to modulate the Generate high frequency that the control grid; is supplied by the fact that the emission of the virtual cathode, which is between the inner screen grid and the input control grid 7 is present, is changed.

For low oscillator amplitudes, the transposition gain will vary of the tube h8 directly with the oscillator amplitude.

The blocking capacitor C12 in series with the grid .4 of the tube I ', and the branch resistance R between grid q and cathode K of the tube I ' a bias resulting from the oscillator amplitude, which via a connection iS is passed to the grid 22 of the intermediate frequency amplifier tube V3. The connection 18 contains the series resistors R2 and R3 and the capacitors C15 and e21, um to screen out pulsating components of the preload.

When the circle of FIG. 5 is in operation, the increased one Bias on the oscillator grid q., Which occurs with an increase in the oscillation amplitude arises, applied to the amplifier grid 22 via the conductor 18. This will make the Conductance of the intermediate frequency amplifier tube h3 and thus the gain in this Tube lowered. Reversing this chain of reactions is accomplished by reducing it caused by the oscillation amplitude. .

Claims (3)

PATEN TANSPItI.CHE: i. Arrangement for heterodyne receivers to regulate the gain by means of a rectified control voltage derived from the oscillator, characterized in that the control voltage acting on an amplifier tube or the mixer tube is so dimensioned that the influence of the change in the oscillator amplitude on the gain of the heterodyne receiver is canceled will. 2. Arrangement according to claim i, characterized in that the control voltage on one lying in the lattice circle of the oscillator tube, with a lattice block condenser Bator bridged resistance is decreased. 3. Arrangement according to claims r and a, characterized in that one is used simultaneously as an oscillator and mixer tube effective tube is used in which the grid electrode located in the cathode compartment, at which the control voltage comes into effect, is adjacent to the cathode and as Oscillator control grid is used.