DE684171C - Self-oscillating mixer stage of a superposition receiver - Google Patents

Description

The invention relates to the known mixer stage of heterodyne receivers, in which the receiving oscillations and the oscillator oscillations are in series Cathode and the same negatively biased control grid of the mixing tube applied are. Considerable distortions occur in such mixer stages when the alternating grid voltage, which is composed of the two voltages mentioned, into the Lattice flow area immersed.

It is therefore known that it is necessary to make the negative bias so large that this disadvantage does not occur. At a mixer stage, which the oscillator oscillation is fed from a special oscillator tube, one arrives in this way without difficulty to the goal, since the amplitude of the oscillator oscillation is known Way by means of the grid current and can keep constant by provides a grid block and a grid bleed resistor on the oscillator tube. These The circuit for limiting the amplitude is, however, in the case of self-oscillating mixing tubes with a common control grid for the received and oscillator oscillations, not applicable, since distortions would then occur as a result of the grid current. If you turn therefore a constant negative grid bias with no amplitude limitation on, the control of the grid current range is unavoidable, as the oscillator amplitudes are very different across the wave range and also at the onset different tubes are not always exactly as big. This disadvantage is caused by the Invention eliminated.

According to the invention, in a self-oscillating mixer of the type mentioned the negative grid bias of the control grid by rectifying the oscillator oscillations generated in an additional rectifier and dimensioned so large that the entire grid alternating voltage of the Mixing tube does not reach the grid current range. In this way, the negative grid bias automatically adapts to the size of the oscillator amplitude generated.

In an anode rectifier, it is known to reduce the grid bias from the input amplitude to make dependent by changing the grid bias on the cathode series resistor of the anode rectifier decreases or by rectifying the receiver -55 catching vibrations in a special rectifier wins. This is intended to be an adjustment the grid prestress to each

occasional reception amplitude can be achieved. These circuits would not be applicable to a mixer stage, since the receiving voltages in this stage are still very small. .; It is also known to eiiie.Ä constant negative grid bias eiaeia .; to use a special oscillator and to rectify the alternating voltage generated by it. However, the object on which the invention is based cannot be achieved with a constant negative grid bias. Furthermore, a special oscillator is not required in the invention. The figure shows an exemplary embodiment of the invention, in which the oscillator oscillations are generated in a known manner by feedback of the oscillator circuit (7) located in the anode circuit of the self-oscillating mixer tube with the feedback coil (ZL ₃ ) located in the cathode line and at the same time in the grid circuit. When the invention is used in this exemplary embodiment, the additional rectifier (3, 6) has a common cathode with the mixing tube. This additional rectifier is in series with a coil (L ₄ ) coupled to the oscillator circuit (7), a load resistor (R), which is also connected to the grid circuit and at which the grid bias occurs, and finally in series with the feedback coil ( L ₃ ). A more detailed description of this figure now follows.

The mixing tube stage contains the mixing tube 1, between its control grid 2 and Cathode 3 of the tunable receiving circuit 4 is located.

This circuit 4 contains a coil L and a variable capacitor C, the rotor plates of which are grounded, and a high-frequency bridging capacitor 5 ″ between the grounded side of the coil and the grounded side of the capacitor C between the one side of the coil L and the grounded cathode circuit the resistance R.

The tube 1 contains two electrode systems which are independent of one another, but which have the cathode 3 in common. The one electrode system consists of the indirectly heated cathode 3, the reception control grid 2, the screen grid 2 ', the anode 5 and the braking grid 5'. This braking grid is located between the screen grid and the anode and has cathode potential due to its connection with the center of the cathode. The grids 2, 1 ' and 5' are arranged cylindrically around the cathode. This electrode system forms the well-known pentode.

The other electrode system contains part of the emitting surface of the cathode and one or more auxiliary anodes, in the present case two such anodes 6 and 6 '. , These auxiliary anodes are not in the elec-ί; electron current flowing through the grids 2, 2 'and 5' i and to the anode, and are v; -y-linked together so that half-wave rectification occurs. The pentode anode 5 is connected to the positive terminal of the voltage source B via the oscillator circuit 7 and an oscillating circuit 8 tuned to the intermediate frequency. The negative pole of B is connected to the grounded side of the resistor, R. The oscillator circuit contains the oscillator _{coil ZL 1} and the tuning capacitor C ₁ , and the oscillating circuit 8 contains the primary coil L ₂ . of the coupling transformer A, bridged by the fixed capacitor C ₂ , which tunes it to the intermediate frequency.

In the grounded cathode lead the coil L _3, which is coupled to the oscillator coil L _1. The diode anodes 6 and 6 'are connected to the ungrounded side of the resistor R via a line in which a coil L _t is located, which is also magnetically coupled _{to the oscillator coil ZL 1.} The screen grid 2 'is connected by a line 10 to a point of the voltage source B which has a less positive voltage than the point to which the anode 5 is connected.

The two variable capacitors C and C ₁ are coupled to one another by the linkage 11. The intermediate frequency occurring at the oscillating circuit 8 is fed to the input 12 of the intermediate frequency amplifier s, the output of which is then rectified in a known manner and made usable. The way it works is as follows:

The signal source coupled to the coil ZL can be the antenna or a high-frequency amplifier stage; In any case, the receiving circuit 4 is tuned to the incoming high frequency, while the circuit 7 determines the frequency of the local oscillator. The coupling M between the coils ZL ₁ and ZL ₃ produces the oscillation and causes an amplitude at the control grid that is to be designated E _1. The coil Li, which is coupled to L ₁ , causes an additional amplitude E ₂ , E ₁ and E _{2 being} in phase with respect to the diode anodes 6 and 6 '.

If one assumes an efficiency of the rectifier of-1000/0, then the DC voltage at the resistor is /? equal to the vertex E ₁ plus the vertex Zr ₂ - If E _{2 is} sufficiently large, the DC voltage at the resistor R (this is the control grid bias of the oscillator) must then exceed the peak oscillation E ₁ on the grid.

th, so that the incoming high frequency can assume a limit value without causing a grid current. R has a value of about 0.5 megohms and the capacitor 5 'has a value of 0.1 or 0.01 microfarads.

Claims (2)

Patent claims: i. Self-oscillating mixer stage of a heterodyne receiver in which the Received vibrations and the oscillator vibrations are applied in series between the cathode and the same control grid, characterized in that the negative grid bias of the control grid by rectifying the oscillator oscillations Generated in an additional rectifier and dimensioned so large that the entire grid alternating voltage the mixing tube does not reach the grid current range. 2. Mixer according to claim 1, characterized in that when the oscillator vibrations are generated by feedback of the oscillator circuit (7) located in the anode circuit of the mixer tube with the feedback coil (L ₃ ) lying in the cathode line and at the same time in the grid circle, the mixer tube and the additional rectifier (3) , 6) have a common cathode and that the additional rectifier (3, 6) in series with a coil (L ₁ ) coupled to the oscillator circuit, a load resistor (R), which is also connected to the grid circuit, and the feedback coil (L ₃ ) lies. 1 sheet of drawings