SU1020969A1 - Frequency converter - Google Patents

Description

The invention relates to radio engineering and can be used in heterodyne (direct conversion) and superheterodyne receivers.

A known frequency converter, ⁵ made on linear controlled resistors. The latter are usually field effect transistors, usually with a symmetrical channel. The specified frequency converter provides an increase in dynamic range and a reduction in crosstalk on linear controlled resistors {j].

However, the known converter does not suppress the local oscillator signal ¹⁵ at the input of the frequency converter.

The closest to the proposed is a frequency converter, 9Ω oscillation circuit comprising an input and two field-effect transistors, the sources of which are connected together and the gates are connected to the terminals of the secondary winding of the balancing transformer paraphase conclusions ob- primary coils ²⁵ which are connected to the LO signal source and the load £ 2].

However, the known frequency converter has a low noise immunity of 30.

The purpose of the invention is to increase noise immunity.

The goal is achieved in that the frequency converter ₃₅ soder- zhaschem input oscillation circuit and two field-effect transistors, the sources of which are interconnected, .a gates connected to terminals of the secondary winding of the balancing transformer paraphase shaper 40, the primary winding terminals of which are connected to a source heterodyne signal, and the load, the input oscillating circuit is connected between the connection point of the sources, and the common 45 bus, and the load is connected between the connection point of the drains and the common bus.

The drawing shows an electrical schematic diagram of the proposed frequency converter.

The frequency converter contains an input oscillating circuit 1 and two field-effect transistors 2 and 3, the sources of which are interconnected, and the gates are connected to the terminals of the secondary winding of the paraphase balancing transformer 4, the terminals of the primary winding of which are connected to the heterodyne signal source 5, and a load of 6.

The frequency converter operates as follows.

The channel of each ID transistor conducts if the gate voltage is greater than the cutoff voltage, i.e. at the peaks of positive half-waves of heterodyne voltage. Since antiphase voltages are applied to the gates, the conductivity G of the parallel-connected channels increases twice during the heterodyne voltage period. Thus, the parallel-connected channels act as a synchronous switch, switching the signal with a frequency of 21 ^. If the frequency 2f ^ is close to the frequency of the input signal f _c , the difference frequency current will flow in the load circuit. A transformation occurs, as it were, on the second harmonic of the local oscillator frequency. However, there are no real currents and voltages with a frequency of 2f ^ in the frequency converter and they are not generated in the circuit.

The proposed frequency converter provides increased noise immunity from 50-60 to 80 dB; increasing the attenuation of the local oscillator signal in the input circuit from 30-40 to 60-70 dB. Other positive qualities of frequency converters on linear, controlled resistors (small crosstalk and a large range of input signals) in the proposed converter are fully preserved.

Claims (1)

A FREQUENCY CONVERTER containing an input oscillating circuit and two field-effect transistors, the sources of which are connected to each other, and the gates are connected to the terminals of the secondary winding of a paraphase balancing transformer, the terminals of the primary winding of which are connected to a heterodyne signal source, and a load, characterized in that, in order to increase noise immunity, the input oscillatory circuit is connected between the connection point ^{1 of the} sources and the common bus, and the load is connected between the connection point of the drains and the common bus.