SU1197039A1 - Self-excited crystal oscillator - Google Patents

Abstract

A QUARTZ AUTOMATIC GENERATOR containing a first field-effect transistor, which is connected according to a common source circuit, a second field-effect transistor, which is connected according to a common-drain circuit, a first capacitor, which is connected between the source of the second field-effect transistor and the gate of the first field-effect transistor, a quartz resonator, first and second the electrodes of which are connected respectively to the drain of the first field-effect transistor and the common bus, characterized in that, in order to improve the frequency stability of the output oscillations, the second a capacitor and an additional resistor, and the crystal resonator is made in the form of a four-electrode crystal resonator, while the second capacitor is connected between the third electrode of the four-electrode crystal resonator v and the gate of the second field-effect transistor, the additional resistor is connected between the quarter electrode of the four-electrode quartz resonator and the gate of the second field-effect transistor.

Description

1 The invention relates to the field of radio engineering and can be used as a source of highly stable harmonic oscillations. The purpose of the invention is to increase the stability of the frequency of the output oscillations. The drawing shows the circuit diagram of the proposed quartz oscillator. The quartz oscillator contains the first I and second 2 field-effect transistors, four-electrode quartz resonator 3, first capacitor 4, second capacitor 5, additional resistor 6. The quartz autogenerator works as follows. When the power source is turned on in the drain of the field-effect transistor 1, voltage fluctuations occur, which arrive at the gate of the second field-effect transistor 2, pass through a four-electrode quartz resonator 3. Fluctuations are made at the source of the second left transistor 2, and then apply to the gate of the first field-effect transistor 1 through the first capacitor. Thus, a closed system is obtained: in which, under conditions of phase and amplitude balance, continuous oscillations occur. The phase balance condition for the proposed quartz oscillator is written as C -btfj + (j, 2irK, (1) where is the phase shift between the voltage at the drain of the first field-effect transistor and on the gate: at the gate of the second field-effect transistor; phase shifts introduced amplifier stages are made respectively on the first and second field-effect transistors; K 0itli. ± 2, .... Since the first field-effect transistor 1 is connected according to the circuit with a common source and the second field-effect transistor 2 - according to the circuit with a common drain, then f. , a, -0. Substituting the values of г g ryeniya (l) is accepted in K "1, consider the value of the phase shift Cf, at which the phase balance condition is fulfilled (1) 9 (f, (Go) -2arctgwCR 7. (2) Denote by ((Ы,) the phase shift introduced by the four-electrode quartz resonator 3 at the frequency C , then choosing the resistance value of the additional resistor 6 and the value of the capacitance of the second capacitor 5 so that (W) 2arctg JR, (3) fulfill the phase balance condition (1 strictly at the resonant frequency of the four-electrode crystal resonator 3, and in the proposed quartz oscillator oscillator oscillations with frequency and, equally th resonance 6) g. The amplitude balance condition in the proposed quartz autogenerator is satisfied by selecting the gain of the cascade performed on the first field-effect transistor 1. The phase balance condition dp of the known device can be written as Cf, + (j + VCw) 2irK. (4) Dn fulfillment of condition (4) it is necessary that (w) be equal to (J (()), when. But the phase shift (fl) introduced by the four-electrode quartz resonator 3 is equal at a frequency different from the resonant one. life bychislena on forKgule v-f - / - f / - ".. h) where Q - is equivalent. good quality; / flcj of the steepness of the phase-frequency characteristic of the oscillatory system at the operating frequency GJ .g. The value of -r- has the largest value of He) at the frequency corresponding to the resonance frequency of the four-electrode quartz resonator 3. Therefore, the Q-factor Qg is equivalent at the resonance frequency. At frequencies other than resonance, the slope of the phase-frequency characteristic decreases, and therefore Q also decreases. And as in the proposed quartz oscillator, the choice of the resistance value of the additional

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the resistor 6 and the capacitance value of the second proposed quartz autograph

If one of the co-generators 5 is provided, the nematode can be higher than the quality factor to the co-operation of the four-electrode quartz-oscillatory system of the known auto-gyne resonator 3 strictly at its oscillator, due to which the resonant frequency is ensured, then it is equivalent to 5%. increasing the stability of the frequency part of the oscillation system of the output oscillations.

Claims (1)

A quartz oscillator containing a first field-effect transistor that is connected according to a common source circuit, a second field-effect transistor that is turned on with a common drain circuit, a first capacitor that is connected between the source of the second field-effect transistor and the gate of the first field-effect transistor, a quartz resonator, the first and second electrodes of which are connected respectively to the drain of the first field-effect transistor and a common bus, characterized in that, in order to increase the stability of the frequency of the output oscillations, a second condense is introduced into it ator and additional resistor, and the quartz resonator is designed as a four-electrode of the quartz resonator, wherein the second capacitor is connected between the third electrode and four-electrode of the quartz resonator of the second gate field effect transistor, a further resistor connected between the fourth electrode and four-electrode of the quartz resonator of the second gate field effect transistor .. d - 1 -F TO P 1Ί 1 J i 6 at =: -Ί - ΙΙ ⁵