DE878969C - Device for influencing the resonance frequency of an electrical oscillating circuit which can be tuned over a larger frequency range - Google Patents

Description

Device for influencing the resonance frequency of an electrical oscillating circuit whose tuning can be regulated over a larger frequency range For modulation-like frequency influencing of a carrier wave, oscillating circuits are used in control transmitter stages to which a shunt circuit or branch is connected, through which a t ' b zn controllable when the oscillating circuits are excited Reactive current flows. In the simplest case, the shunt circuit can consist of a reactance that can be changed in terms of the modulation frequency. If the oscillating circuit, as is assumed in the present case, can be tuned over a larger resonance frequency range, this generally results in a frequency modulation level that is variable with the tuning, in the case of the usual frequency modulation circuits.

This deficiency is eliminated by the subject matter of the invention, and, Although the following findings led to the invention: It is possible to use one under the marked prerequisites are tuning-independent, i.e. constant frequency deviation to be reached - if the shunt branch is the same -, verti'- is the series connection of a reactance with such an ohmic resistance that the size of the blind conductance of the shunt branch within the range Aer Tuning frequencies of the oscillation circuit is to be regarded as almost constant. Regardless of this Measure, it is also possible to reduce the frequency deviation by such a! Connection of the shunt branch to the resonant circuit, one of which is reactance in a fixed part that can be changed for the purpose of circle voting is subdivided, to achieve that the dependence of the effective size, the current flow in the tributary branch from the resonance frequency17 of the oscillation circuit in favor of stroke constancy the tuning range of the oscillation circle is different than when the dependency in a proportionality of the tributary flow and the terminal voltage of the Oscillation circuit would be.

Now is the achievement of the goal set through the application only one of the listed switching measures not in all. Cases possible. Furthermore If only one of these measures is used, this is usually the production-related one The disadvantage is that switching means are used to build the circuit need to find whose. Size does not correspond to an electrical standard size. on The reason for this is that the invention provides optima.Ie modulation constant to win over the tuning range of the oscillation circuit that both switching measures. applied at the same time and in their amount of effect corresponding to the stated purpose be compared to each other.

In Fig. I the capacitive reactance, the oscillation circuit is divided into the variable part 2 and the fixed part 3 . i is the self-induction of the circuit, which is provided for the purpose of influencing the modulation frequency resonance frequency, shunt branch is connected to the circuit points 4 and 5 . It consists of the capacitor 7, which is in series, with the ohmic resistor 6 and the control switching device 8. Both switching measures, namely the subdivision of one of the oscillating circuit resistors into a fixed and a variable one. Part and connection of the l '"connection branch to one of these reactance parts on the one hand, and the formation of the shunt branch in the form of a series connection of ohmic resistance and binding resistance on the other hand, each cause an influence on the resonance circuit tuning in and of itself With regard to their amount of action, the two switching measures are coordinated with one another in such a way that an optimal frequency constant results for the tuning range of the oscillation circuit.

Fig. 2 shows another Ausdührungsbeispiel the circuit in principle the same. The reactance tube ii has taken the place of the reactance of the shunt branch. Discharge current has a reactance component. In order to achieve the reactive resistance component of the discharge current, the capacitor 9 and the high-ohmic resistor io connected in series with this are provided, at the junction of which the grid of the reactance tube is connected. The size of the reactive current flow through the tube ii depends on the size of the AC potential at circuit point 4, i.e. also the size of the reactive current component of the shunt branch formed in the present case by tube ii, is dependent on the subdivision of resonant circuit reactance 2, 3 which determines the size of the changeover potential at circuit point 4, precisely as in the exemplary embodiment in FIG . i. however, this also the shunt circuit of Fig. 2 gleichwertiist d # emjenigen FIG. i with respect to the elektrischeu effect of the series resistor 6, the control grid circuit is the tube ii dimensioned such that as a result at # v "-senheit leading to resistance io parallel capacitance 14 is a real component to which by d ie tube ii superimposed reactive current flowing and thus an influence on the frequency modulation level in the sense of a reduction g 2n of its dependence t 'on the tuning of the resonant circuit 1, 2, 3 results.

During by exemplary * ührungsheispiel FIG. I only a one-half times a given frequency shift in operation of the switch is possible to 8, the Reaktanzröhrenschaltung FIG. 2 performed so that by means of the. Modulation voltage connected to terminals 13! Any frequency modulation of the resonance frequency of the oscillation circuit is possible. The capacitor 1: 3 is only used for high-frequency bridging of the modulation voltage source. Fig.:2 is in principle equivalent to the circuit diagram of Fig. I. The anode of the tube ii has been connected to the circuit point 16 instead of to the circuit puDI #: t 4 via: the line 15 without affecting the fundamental electrical equivalence of the two circuits.

Claims (1)

PATENT CLAIM: Device for influencing the resonance frequency of an electrical oscillating circuit that can be tuned over a larger frequency range by means of a shunt branch which causes a controllable reactive current flow, characterized in that optimum frequency deviation constancy over the tuning range of the oscillating circuit through simultaneous application of the following switching measures and corresponding Adjustment of the amounts of effect1 on each other is achieved: a) The tributary branch is connected to the oscillation circuit, whose one reactance is divided into , Z, a fixed part that can be changed for the purpose of circuit tuning, so that the effective magnitude of the current flow is dependent in 'l', Teb.-nschlusszwe # i # -of the resonance frequency of the oscillation circuit in favor of the stroke constancy over the tuning range of the oscillation circuit is different than when the dependence in a proportionality of the tributary current flow s and the terminal voltage of the Schwin- #und «slzreis would exist. nb) - 'According to the second switching measure, the shunt branch of the series, b L, circuit of a reactance with an ohmic resistance dimensioned so that the frequency dependence of the size of the blind line ZD Z, value of the shunt branch is noticeably reduced.