UA150736U - GENERATIng DEVICE - Google Patents

Abstract

A signal-generating device includes a first quartz discriminator of the reference oscillation mode, a second quartz discriminator of the thermosensitive oscillation mode, a two-channel analog-to-digital converter. The output of the first discriminator is connected to the first input of the analog-to-digital converter. The output of the second discriminator is connected to the second input of the analog-to-digital converter. The output of the analog-to-digital converter is connected to the input of the compensation signal generation circuit, a multi-channel direct synthesis composer, the first channel of which is used to discriminate the frequency of the reference mode of the quartz resonator. The second channel is used to discriminate the frequency of the thermosensitive mode of oscillations of the quartz resonator. The third channel is used for formation of reference oscillations in the spectrum transfer scheme. The output of the first channel of the direct synthesis composer is connected to the input of the first quartz discriminator. The output of the second channel of the direct synthesis composer is connected to the input of the second quartz discriminator. The output of the third channel of the direct synthesis composer is connected to the input of the spectrum transfer scheme. A bipolar quartz resonator with one pair of electrodes is used, the oscillation stabilization function of which is combined with the function of identifying the current state of the piezoelectric element. Additionally, the first bandpass filter and the second bandpass filter are introduced. The first terminal of the quartz resonator is connected to the first terminals of the discrimination circuits of the first and second quartz discriminators. The second terminal of the quartz resonator is connected to the inputs of the first and second bandpass filters. The output of the first bandpass filter is connected to the second terminal of the discrimination circuit of the first quartz discriminator, and the output of the second bandpass filter is connected to the second terminal of the discrimination circuit of the second quartz discriminator.

Description

The utility model belongs to signal generation and shaping devices, in particular to highly stable sources of reference oscillations based on digital frequency synthesis with thermocompensation circuits, and can be used in the field of digital radio communication, radio broadcasting and television, radar, radio navigation and measurement technology.

A known generating device based on a two-frequency generator |1)|, which contains an amplifier on a transistor, two phasing capacitors, a load IC circuit, two control circuits with varicaps and resistors connected in series, a two-section inductor, the first section of which is connected to the anode through a separation capacitor of the first varicap, the second section of which is connected to the anode of the second varicap through the separation capacitor, and the common point of both sections is connected to the base of the transistor, the phase shifter and the attenuator are connected in series, and the input of the phase shifter is connected to the output of the generator, and the output of the attenuator is connected to the base of the transistor amplifier.

The disadvantages of this device are the low stability of the two-frequency oscillation mode, which is due to the use of low-Q IS circuits of the generation frequency assignment and compensation of temperature instability only for low-frequency oscillation of the difference frequency. This significantly reduces the accuracy characteristics of the device and limits its functionality.

Also known is a generating device |2)Ї, which contains a reference two-frequency quartz generator, which is excited at two frequencies of the first and third mechanical harmonics of the quartz resonator, the first frequency divider by three, the second frequency divider with a coefficient of Щ, a mixer, at the output of which a signal of the difference frequency Dg-iz3/3 is allocated, a pulse counter for forming a temperature-dependent digital code M(T), a microcontroller for forming a special control code M(T) based on the code M(t) and a digital synthesizer of the frequency of direct synthesis, by program change whose frequency is compensated for the temperature instability of the reference frequency on the basis of the control code M(T), and the output of the digital frequency synthesizer is the output of the generating device.

The disadvantage of this device is the use of oscillatory excitation of a two-frequency quartz resonator under conditions of increased total excitation power, which significantly increases the temperature component of the instability of the output signal frequency. In addition,

The use of a direct synthesis frequency synthesizer to form the output signal significantly worsens its spectral composition and limits the frequency range of the device.

The closest to the proposed device is the generating device |Zi|, which contains a multi-frequency quartz resonator with two pairs of electrodes for excitation of oscillations of the reference and temperature-sensitive modes, connected to the corresponding quartz discriminators of the reference and

C5 temperature-sensitive oscillation mode, a two-channel analog-to-digital converter, a compensation signal generation scheme and an oscillation spectrum transfer scheme based on a phase auto-frequency adjustment system, which consists of a direct synthesis synthesizer, a phase detector, a low-pass filter, a frequency divider and a voltage-controlled generator.

The disadvantage of this device is the use of a multi-frequency quartz resonator with separate electrodes, which, due to the presence of spatial gradients between the areas of excitation of oscillations, leads to significant dynamic errors of thermal compensation and an increase in the thermodynamic instability of the output signal frequency of the generating device. In addition, the practical implementation of the prototype device (IZ) requires the manufacture of special multi-frequency quartz resonators, which significantly impairs the manufacturability of the design of the generating device and limits its wide use.

The useful model is based on the task of increasing the stability of the output signal frequency of the generating device and improving the manufacturability of its design.

The task is solved by the fact that the signal generating device contains the first quartz discriminator of the reference mode of oscillations, the second quartz discriminator of the temperature-sensitive mode of oscillations, and a two-channel analog-to-digital converter. The output of the first discriminator is connected to the first input of the analog-to-digital converter. The output of the second discriminator is connected to the second input of the analog-to-digital converter. And the output of the analog-to-digital converter is connected to the input of the compensation signal generation scheme, a multi-channel synthesizer of direct synthesis, the first channel of which is used to discriminate the frequency of the reference mode of oscillations of the quartz resonator. The second channel of which is used to discriminate the frequency of the temperature-sensitive oscillation mode of the quartz resonator.

And the third channel of which is used to form a reference oscillation in the spectrum transfer scheme. The output of the first channel of the direct synthesis synthesizer is connected to the input of the first quartz discriminator. The output of the second channel of the direct synthesis synthesizer is connected to the input of the second quartz discriminator. And the output of the third channel of the direct synthesis synthesizer is connected to the input of the spectrum transfer circuit. A bipolar quartz resonator with one pair of electrodes is used, the function of stabilizing its oscillations is combined with the function of identifying the current state of the piezoelectric element. Additionally, the first bandpass filter and the second bandpass filter are introduced. The first output of the quartz resonator is connected to the first outputs of the discrimination circuits of the first and second quartz discriminators. The second output of the quartz resonator is connected to the inputs of the first and second bandpass filters. And the output of the first bandpass filter is connected to the second output of the discrimination circuit of the first quartz discriminator, and the output of the second bandpass filter is connected to the second output of the discrimination circuit of the second quartz discriminator.

Drawings explain the essence of a useful model.

In Fig. 1, a signal generating device, which contains a bipolar multi-frequency quartz resonator 1, bandpass filters of the reference mode of oscillations 2 and temperature-sensitive mode of oscillations 4, quartz discriminators of the reference mode of oscillations Z and temperature-sensitive mode of oscillations 5, two-channel analog-to-digital converter (ADC) b, compensation signal generation scheme 7, oscillation spectrum transfer scheme 8 based on the phase auto-frequency adjustment system, which consists of a direct synthesis synthesizer 9, a phase detector 10, a low-pass filter (LFF) 11, a frequency divider 12 and a voltage-controlled generator (VCG) 13.

The generating device works as follows.

Bipolar multi-frequency quartz resonator 1 is used in the mode of simultaneous excitation of the reference and temperature-sensitive oscillation modes, which minimizes gradient and dynamic errors caused by various influencing factors, primarily temperature.

Two-frequency excitation of the quartz resonator (CR) is necessary to combine the frequency stabilization function with the measurement function, which provides simultaneous identification of the thermal state of the CR (4).

The thermal state of the CR is one of the most significant factors that determines the stability of the generated oscillations. The dependence of the natural resonance frequencies of the CR on the thermal state of the resonator is determined by the physical properties of the piezoelectric element and the structural

With the features of electrodes, quartz holders, etc. A change in the thermal state of the CR can be caused by both external factors (change in ambient temperature) and internal factors (due to self-heating of the piezo plate).

In the proposed generating device (Fig. 1), standard CRs can be used, for example, AT-section resonators (УЧИ/В) with oscillations of the first and third harmonics, or double-turned SS-section resonators (УЧБИ/у/В) specially designed for this purpose. Resonator

ZO-section (у-22752", В--34206 has the possibility of simultaneous excitation of three vibration modes (А, В,

C), at the same time, mode B has a temperature coefficient of frequency of about 25-10-5 1/С" under the condition of its high linearity in Fig. 2.

To identify temperature disturbances, the estimating function АКЕ(Т) of the differential oscillation of the temperature (В) and reference (С) modes and yveee with different temperature-frequency characteristics (ТХ) is used:

DA(T)-AivVEk(T)-ANT), (1) where Dineek(T), DIT(T) are the temperature shifts of the frequencies of the reference and temperature modes of oscillations of the inee and

It.

Since all modes (A, B, C) occupy the same volume of the resonator, this allows using mode (C) to generate reference oscillations, and mode (B) as a sensor of the instantaneous temperature in the active zone, which excludes gradient and dynamic errors inherent in standard methods of thermocompensation and thermostating |4|.

At the same time, sudden changes in the thermal regime of the CR (its excitation conditions) lead to a significant distortion of the TFC, which requires taking into account the thermodynamic component of frequency instability, which may exceed the frequency shifts in the pseudostatic regimes of the CR. at. that KAE / t gdh

In fig. Here are the typical thermodynamic characteristics for different powers of jump-like excitation of 5C-section resonators. Analysis of the data shows that the changes in the excitation power of the ARze2100 μW CR are too large for highly stable generation devices. At the same time, the limitation of excitation power variations at the level of DARzb: 10 μW allows the thermodynamic component of frequency instability to be neglected within 260-1-1038--1.109 for 5C resonators - sections. At the same time, there is a rather significant reduction in the duration of the transient process by frequency (more than 2...3 times), which, however, significantly decreases with variations in the excitation power of ARzv2500 μW (41.

To increase the stability of the frequency of the output signal of the generating device and improve the manufacturability of its design, a two-pole two-frequency quartz resonator 1 is proposed, the function of stabilizing the oscillations of which is combined with the function of identifying the current state of the piezo crystal element to be used as a reference circuit of the frequency discriminators of the oscillations of the Jennieguer mode and the oscillations of the Yt mode, which operate in the microexcitation mode, which ensures a high steepness of transformation and stability of discrimination frequencies (Fig. 1).

The two-frequency quartz resonator is connected to the discrimination circuits of the first quartz discriminator of the reference mode of oscillations iivge through the first band-pass filter 2, and to the discrimination circuits of the second quartz discriminator 5 of the temperature-sensitive oscillation mode yt through the second band-pass filter 4, which makes it possible to compete with the oscillations of the Ginee and yt modes and ensures high competition stability of the two-frequency excitation mode of KR 1.

Both frequency discriminators perform the function of "frequency-voltage" conversion and are the main elements of a two-channel system of an automatic frequency adjustment system (APU), which also contains a two-channel ADC 6, a compensation signal generation circuit 7 and a two-channel direct synthesis frequency synthesizer (005) 9. At the output of the first frequency discriminator Z is formed a Onee voltage proportional to the Lineye frequency shift, which enters the first input of the ADC 6, at the output of the second frequency discriminator 5, a voltage Ot is formed, proportional to the shift of the Dit frequency, which enters the second input of the ADC 6. At the output of the ADC 6, a two-parameter the digital sequence Mzp, which enters the compensation signal generation circuit 7. The compensation signal circuit 7 forms a digital code M, which is used to configure the three-channel coherent synthesizer of direct synthesis (KSPS) 9. The first channel of the KSPS 9 is used to form the oscillation of the reference frequency, which enters at the input of the first quartz discr iminator Z, and the second channel of the KSPS - for forming the oscillation of the thermosensitive frequency yt, which enters the input of the second quartz discriminator 5, thereby forming a two-channel AFC system.

The first quartz discriminator Z and the second quartz discriminator 5 are built according to similar schemes based on integrated specialized microcircuits TVA1205 (K174URI) on

Koo) fig. 4.

The TVA1205 integrated circuit contains an amplifier-limiter of the input signal, a quadrature frequency detector of the balanced type and a low-frequency mismatch signal amplifier with electronic control of the transmission coefficient using a resistor H2 (82). The multi-frequency quartz resonator 1 VO is connected to the discrimination circuits (pins 7 (7) and 9 (9) through bandpass IC filters 2 and 4 (1106 and I 1"C6). This frequency quartz discriminator provides a slope of the discrimination characteristic no worse than 0, 2...0.5 V/kHz, while the range of electronic adjustment of the transmission coefficient is 60 dB (Fig. 4).

The oscillation spectrum transfer scheme 8 consists of a phase detector 10, a low-pass filter 11, a voltage-controlled generator 13 and a frequency divider 12 and is a system of phase automatic frequency adjustment (FAPU). At the input of the PLL system (at the first input of the phase detector 10), the temperature-compensated oscillation of the reference frequency of cells is supplied from the third output of the KSPS 9, and at the second input of the phase detector 10 - oscillations from the voltage-controlled generator 13 with the frequency oit/p. where n is the division coefficient of the frequency divider 12. At the output of the phase detector 10, an error signal is formed, proportional to the difference in the phases of the signals at its inputs, which, after correction with the help of a low-pass filter 11, which determines the dynamic properties of the PLL system, is used to control the frequency of the voltage-controlled generator 13. Therefore, the frequency of the output signal of the generating device will be equal to Irit Z Pot,

The proposed generation device provides higher stability of the frequency of output oscillations by increasing the accuracy of compensation of the temperature instability of the quartz resonator in the two-frequency excitation mode with current identification of its thermal state and reducing the thermodynamic error of identification in comparison with circuits with a separate temperature sensor by one to one and a half orders of magnitude, depending from the type of quartz resonator.

Sources of information: 1. Pat. 29643А Ukraine, MKI 6 NOZS 3/09. Frequency-modulated generator /F.F. Kolpakov,

S.K. Pidchenko, G.L. Khilchenko; applicant and patent owner Khmelnytskyi. national university. - MO 96041345; statement 04/05/1996; published 11/15/2000, Bull. Mo. 6th. - 5 s: fig.

2. M. Buiapik. Ap itrgometepi ip (Pe Ietregaishge-sotrepzaiva 005 /U. ByugapikK, I. Vaiag, M.

Mipunk //Rhos. ой Te 2001 IEEE/EIA Ipiegpaiyopa! Egedoepsu Sopit! Dinner - R. 662-664.

Z. Pat. Mo. 86099 Ukraine, IPC H 031 89/00. Generating device /S.K. Pidchenko, A.A.

Taranchuk, V.I. Stetsyuk, O.V. Kalvatinsky; applicant and patent owner Khmelnytskyi. national university. - MO and 201308554; statement 07/08/2013; published 10.12.2013, Bull. Mo 23. - 8 s: ill. 4. Pidchenko S.K. Theory and implementation bases of invariant multi-frequency piezo-resonant devices and systems / S.K. Pidchenko. - Khmelnytskyi: KhNU, 2014. - 400 p.

Claims (1)

FORMULATION OF THE USEFUL MODEL A signal generating device comprising a first quartz discriminator of the reference oscillation mode, a second quartz discriminator of the thermally sensitive oscillation mode, a two-channel analog-to-digital converter, and the output of the first discriminator is connected to the first input of the analog-to-digital converter, the output of the second discriminator is connected to the second analog input -digital converter, and the output of the analog-to-digital converter is connected to the input of the compensation signal generation scheme, a multi-channel direct synthesis synthesizer, the first channel of which is used to discriminate the frequency of the reference mode of oscillations of the quartz resonator, the second channel of which is used to discriminate the frequency of the temperature-sensitive mode of oscillations of the quartz resonator, and the third channel of which is used to form a reference oscillation in the spectrum transfer scheme, and the output of the first channel of the direct synthesis synthesizer is connected to the input of the first quartz discriminator, the output of the second channel of the direct synthesis synthesizer is connected to the input of the second quartz discriminator, and the output of the third channel of the direct synthesis synthesizer is connected to the input of the spectrum transfer circuit, which differs in that a bipolar quartz resonator with one pair of electrodes is used, the function of stabilizing the oscillations of which is combined with the function of identifying the current state of the piezoelectric element, the first bandpass filter and the second bandpass filter are additionally introduced, and the first output of the quartz resonator is connected to the first outputs of the discrimination circuits of the first and second quartz discriminators, the second output of the quartz resonator is connected to the inputs of the first Zo and the second bandpass filters, and the output of the first bandpass filter is connected to of the second output of the discrimination circuit of the first quartz discriminator, and the output of the second bandpass filter is connected to the second output of the discrimination circuit of the second quartz discriminator. Dan Tae and Tk | mn Ky Fig.