DE1279781B - High frequency resonant circuit - Google Patents

Description

High-frequency resonant circuit The invention relates to a high-frequency resonant circuit arrangement, in which the current-carrying input electrode of an amplifier element, e.g. B. the Electrode of an electron tube, at a high frequency leading point of a resonant circuit inductance lies and a point of this inductance via a high-frequency choke and further a tap point of the resonant circuit capacitance is connected to ground, where a Resistance for generating bias is located in the cathode branch.

The invention is based on the idea that in the course of downsizing (Miniaturization) of the circuitry of electronic devices is necessary that To reduce the number of switching elements as much as possible, so that it is expedient is, by selecting the material of a high frequency coil, still the function of a To give resistance.

In the case of a circuit arrangement of the type mentioned at the outset, this will be the case reached when, according to the invention, a point of the circuit with the battery feed point, preferably earth, connected via a high-frequency choke wound from resistance wire, whose number of turns corresponds to the desired high-frequency impedance and whose ohmic resistance Resistance is the value required to bias the current-carrying electrode having.

Because the resistance in the throttle branch is no longer for high frequency is bridged, it can result that it is with a transformed value at the connection point the throttle occurs and possibly an oscillating circuit connected there dampens. It is therefore advisable to connect the throttle to such a point which has a minimum of the high-frequency voltage or a very low one anyway Impedance shows in such a way that the transformed value of the resistance component is not noticeable in a disturbing way.

The invention is illustrated below with reference to the drawing, for example explained in more detail that a high-frequency band filter input stage of a radio receiver shows.

The input oscillations are fed from the terminals 1 to a first inductance 2 to which the series connection of two resonant circuit capacitors 3 and 4 is connected in parallel, the tapping point of which is grounded. The inductance 2 is connected to a secondary inductance 5, one end of which is connected to the cathode of an electron tube 6 and the other end of which is connected via a separating capacitor 7 to the grid of this tube. The series circuit of two resonant circuit capacitors 9 and 10 , the connection point of which is grounded, is connected to the inductance 5 in parallel. The ratio of the capacitances of the capacitors 9 and 10 can be chosen as desired, preferably unequal; a setting between a pure grid base circuit and a pure cathode base circuit can thus be obtained.

In order to connect the current-carrying cathode of the tube 6 to the earthed pole of the supply source, according to the invention, the choke 11 is switched on between earth and a tapping point of the inductance 5; this choke is made of insulated resistance wire, possibly wound on a ferromagnetic high-frequency core, and has a number of turns which is so large that the required impedance for high frequency is achieved. The material and the thickness of the wire, taking into account the length of the turns and the number of turns, are chosen so that the ohmic resistance of the choke 11 has the correct value so that the correct mean bias voltage results from the electrode current during operation. A smoothing of this bias voltage is not necessary, since the alternating potential of the cathode of the tube 6 is determined by the connected end point of the inductance 5 anyway.

The grid of the tube 6 is via a bleeder resistor 12 with a Potential point connected, e.g. B. with earth or a supplying a control voltage Point 13.

The choke 11 is preferably connected to a point of the inductance 5 which has approximately the same tap ratio at the resonant circuit as is caused by the capacitive voltage divider from the capacitors 9 and 10. But especially if the tap ratio (ratio of the capacitance values of the capacitors 10 and 9) is large and / or if the high-frequency impedance of the wire-wound inductor 11 is large compared to its ohmic resistance, it is also possible to connect the inductor 11 to the connection point of the coil 5 to be connected to the cathode of the tube 6, whereby a tap on the coil 5 can be saved. It must be taken into account whether the transformed value of the choke 11 that appears parallel to the coil 5 and thus on the resonant circuit results in a negligible or inadmissible change in the resonant circuit impedance. If necessary, this transformed value can also be used to bring the resonant circuit damping to the desired value.

Claims (2)

Claims: 1. High frequency resonant circuit arrangement, in which the current-carrying input electrode of an amplifier element, e.g. B. the Electrode of an electron tube, at a high frequency leading point of a resonant circuit inductance lies and a point of this inductance via a high-frequency choke and further a tap point of the resonant circuit capacitance is connected to ground, where a Resistance for generating bias is located in the cathode branch, characterized in that that the choke (11), whose number of turns corresponds to the desired high-frequency impedance, is wound as a resistance wire and its ohmic resistance is used for the bias the current-carrying electrode has the required value and that the throttle (11) between one, preferably having a minimum of the high-frequency voltage, Point of the resonant circuit inductance (5) and the battery feed point, preferably Earth, is on. 2. Circuit arrangement according to claim 1, characterized in that the choke (11) is connected to a point of the inductance (5) which has approximately the same tapping ratio as the capacitive voltage divider (9, 10). Considered publications: pradio und fernsehen «1962, pp. 662 to 665.