SU508893A1 - Thermal compensation device resonant circuit - Google Patents

Description

one

This invention relates to radio engineering and may be used in reference generators.

A device for thermal compensation of a resonant circuit is known, which contains three voltage dividers connected in parallel, the first of which is thermally dependent, and the middle point of the second voltage divider is connected through a corresponding diode to the middle point of the first and third voltage dividers, and a varicap incorporated in the resonant circuit and connected to a resistor.

The purpose of the invention is to increase thermal stability in the temperature range.

For this, the resistor is connected to the midpoint of the third voltage divider, and the diodes are connected to the midpoint of the second divider by the same electrodes.

The drawing shows an electrical schematic diagram of the proposed device.

The thermal compensation device of the resonant circuit of the resonator 1, included in the generator assembled on transistors 2 and 3, contains three voltage dividers connected in parallel, the first of which consists of a thermistor 4 and a resistor 5, the second of resistors 6 and 7 resistors 8 and 9, diodes 10 and 11, through which the middle point of the second divider, to which diodes 10 and 11 are connected by the same electrodes, is connected to the middle points of the first and third divider, respectively, and the compensating varicap 12, included in the resonant circuit Natori 1 and connected to a resistor 13 which is connected to the middle point of the third voltage divider.

The device works as follows. At normal ambient temperature (+ 20 ° C), the diodes 10 and 11 are displaced in the forward direction and current flows through them, and an initial displacement is applied to the compensating varicap 12.

With increasing temperature, the frequency of the resonator 1 with a negative temperature coefficient of frequency decreases, and the resistance value of thermistor 4 decreases. The midpoint potential of the first voltage divider, consisting of a thermistor 4 and a resistor 5, and the current through the diode 10 increases. This leads to an increase in the potential of the midpoint of the second voltage divider, consisting of resistors 6 and 7, and to a decrease in the current through diode 11. As a result, the potential of the midpoint of the third voltage divider, consisting of resistors 8 and 9, and a shift on the compensating the varicap 12 is increased, and the frequency of the oscillator assembled on transistors 2 and 3 rises. Thus, reducing the frequency of the resonator

1 with increasing ambient temperature

the medium is compensated for by changing the capacitance of the compensating varicap 12.

At a certain temperature near the temperature at which the frequency-temperature characteristic of the resonator 1 has an inflection point, the potential of the middle points of the second and third voltage dividers is equalized, and the current through diode 11 becomes zero. With a further increase in temperature, mixing, the compensated varicap 12 remains constant, and the change in the generator frequency is determined by the temperature coefficient of the frequency of the resonator 1, which is close to this temperature.

When the temperature decreases below -20 ° C, the frequency of the resonator 1 increases, and the resistance of the thermistor 4 increases. The midpoint potential of the first voltage divider decreases, and the current through the diode 10 decreases. This causes a decrease in the potential of the midpoint of the second voltage divider and an increase in the current of the diode 11, which leads to a decrease in the mixing voltage of the varicap 12, and, consequently, of the generator frequency. The initial offset of the diode 10 is chosen such that the potentials of the midpoints of the first and second voltage dividers equalize near the temperature at which the frequency-temperature characteristic of the resonator 1 has

the second inflection point, and where the temperature coefficient of frequency changes its sign. With a further decrease in temperature, the offset on the compaction varicap 12 remains constant, and the change in the frequency of the generator is determined by the temperature coefficient of the frequency of the resonator 1.

For thermal compensation of the resonant circuit of the resonator 1 with a positive temperature coefficient of frequency in the circuit, the switching voltage of the diodes 10 and 11 is changed, and the thermistor 4 and the resistor 5 change places.

Claims (1)

Invention Formula The thermal compensation device of a resonant circuit containing three voltage dividers connected in parallel, the first of which is thermally dependent, and the middle point of the second voltage divider is connected via a corresponding diode to the middle point of the first and third voltage dividers, and the varicap incorporated in the resonant circuit and Connected to a resistor, characterized in that, in order to increase the thermal stability in the temperature range, the resistor is connected to the midpoint of the third voltage divider, and the diodes are connected dinene to the midpoint of the second divider of the same electrodes. .p / 5 U