SU1185567A1 - Frequency converter with sinusoidal oscillator voltage - Google Patents

Abstract

A FREQUENCY CONVERTER WITH SINUSOIDAL VOLTAGE HETERODINE containing a transformation element, the first input of which is the input voltage of the input signal, the second input is connected to the output of the local oscillator, and the output is connected to a load that differs from that in order to expand the dynamic range of the oscillator, and the output is connected to the load, which is connected to the output of the oscillator, which is connected to the output of the local oscillator, in order to expand the dynamic range of the oscillator, and the output is connected to the load, which is connected to the output of the oscillator, which is connected to the output of the local oscillator. the electronic key, connected in parallel with the first input of the transforming element, and connected in series and connected between the output of the local oscillator and the control input of the electronic key a new corrector, a high-frequency converter, a pulse shaper, and coz (L-amplifier amplifier. 00 A SPA:

Description

The invention relates to radio engineering and can be used in radio receivers.

The chain of the invention is the expansion of the dynamic range of mutual modulation.

In FIG. 1 shows a functional electric circuit of a frequency converter with a sinusoidal local oscillator voltage; in FIG. 2 is a timing diagram explaining the operation of the converter.

A frequency converter with a sinusoidal voltage of the local oscillator contains a converting element 1, made, for example, on diodes and transformers, a load 2, a local oscillator 3, an electronic switch 4, a phase corrector 5, a high-frequency rectifier 6, a driver 7, a pulse matching amplifier 8.

A frequency converter with a sinusoidal local oscillator voltage works. in the following way.

From the output of the local oscillator 3, the oscillations (Fig. 2a, 1 ^ triple through the phase corrector 5, are fed to the input of the high-frequency rectifier 6. Fig. 1c shows a graph of the voltage at its output. In shaper 7, pulses are generated from this voltage, which through the matching amplifier 8 control the electronic key 4 (Fig. It). The pulse duration is selected in accordance with the time interval during which the diodes of the converting element 1 go from closed to open and vice versa (tj-tj). Using phase corrector 5 (phase shifter, phases The new shift of which depends on the frequency) the optimal phase relation between the pulses and the process of the changing differential resistance of the converting element 1 is established and maintained in the frequency range. In the low-frequency region, this corresponds to the coincidence of the middle of the pulse with the moment the voltage of the local oscillator 3 passes through zero. partially shunts the input of the converting element 1, interfering signals are attenuated, which leads to a decrease in the combination components intermodulation, i.e. to expand the dynamic range of intermodulation. During the time from to i ₃ (Fig. 1 g), when the diodes of the converting element 1 are open, the electronic switch 4 is closed and the useful signal passes without attenuation. Therefore, the introduction of an electronic switch 4 into a frequency converter with a sinusoidal local oscillator voltage does not significantly affect the transmission coefficient. The nonlinear distortions that occur in the electronic key 4 itself are much smaller than in the converting element 1, since the diodes 9 of the electronic key 4 interfere with the signals through the resistor 10, the diodes 9 are opened by the pulse voltage and, in addition, are only open in the open state over a short period of time. The converting element 1 at this time is still weakly open and practically does not let in that small fraction of distortions that occurs directly in the electron key 4.

VNIIIPI Order 6436/57

Circulation 871 Subscription

Branch of PPP Patent '' »

Uzhhorod, Project 4,

Claims (1)

FREQUENCY CONVERTER With a SINUSOID VOLTAGE HETERODYNES, containing a converting element, the first input of which is the input voltage input, the second input is connected to the local oscillator output, and the output is connected to the load, characterized in that, in order to expand the dynamic range for mutual modulation, an electronic key is included, included parallel to the first input of the converting element, and in series connected and connected between the output of the local oscillator and the control input of the electronic key phase corrector, high-frequency ryamitel, pulse shaper and matching amplifier.