RU144346U1 - SAW GENERATOR WITH DISCRETE TEMPERATURE COMPENSATION AND FREQUENCY CORRECTION - Google Patents

Abstract

A SAW generator with discrete temperature compensation and frequency correction, containing an amplifier on a transistor according to the scheme with a common collector between the common wire and the emitter, and also between the base and emitter of which phasing capacitors are connected, and a buffer amplifier is connected to the emitter of the transistor, and the input terminals of the SAW filter are connected between the base of the transistor and the common wire of the source, and the output terminals of the SAW filter are connected between the common wire and the first output of the inductance, characterized in that a resistor is introduced into the circuit a torus, a capacitor, a varicap, the anode of which is connected to a common wire, and the cathode is connected to the first terminal of the inductance, the second terminal of which is connected to the first terminal of the capacitor and the first terminal of the resistor, and the second terminal of the capacitor is connected to the common wire, and the following nodes are introduced: temperature sensor , analog-to-digital converter, processor, first and second digital-to-analog converter with current output, current-to-voltage converter so that the output of the current-to-voltage converter is connected to the second output of the resistor RA, and the outputs of the first and second digital-to-analog converters with a current output are connected to the input of the current-to-voltage converter, each input of which is connected to the first and second output of the processor, which has four inputs - the first, second, and third inputs for programming the processor, and the fourth input is connected the output of an analog-to-digital converter, to the input of which the output of the temperature sensor is connected.

Description

The utility model relates to radio engineering and can be used to improve the temperature stability of the frequency and create high-frequency generators on surface-acoustic waves (SAWs).

Generators based on surface acoustic waves are used as reference generators of stable oscillations in the frequency ranges 100-2000 MHz and are used without additional frequency multiplication, which is an advantage over widely used generators based on volume acoustic waves. However, SAW generators, especially with extended frequency tuning, have insufficient temperature stability of the output high-frequency oscillations in a wide temperature range [Filters on surface acoustic waves (calculation, technology, application): Trans. from English / Ed. G. Matthews. - M. Radio and Communications, 1981].

The use of two devices with a surfactant with a different temperature coefficient or a surfactant device made of composite materials for temperature stabilization of the frequency of a SAW generator causes technological difficulties in obtaining the exact value of the required nominal frequency, increasing the cost and complexity of the generator. Creating a temperature-dependent control action to reduce the deviation of the generator frequency from the set value is one of the methods of frequency stabilization.

A known method of thermal stabilization in an oscillator with a device for surfactants, based on the introduction of feedback that changes the frequency of the oscillator in such a way that the temperature deviation of the frequency is compensated [Dvornikov A.A., Ogurtsov V.I., Utkin G.M. Stable generators with filters on surface acoustic waves. - M. Radio and Communications, 1983, p. 117]. This method allows to improve the temperature stability of the frequency up to 30 times, for generators with a device for surfactants from materials with a low temperature coefficient, such as quartz ST-cut.

There is also known a method in which a temperature-dependent control voltage is generated, applied to the input of a SAW generator controlled by voltage, performed on a SAW resonator. An example implementation is the patents US 4,011,526 and US 2007/0096839 A1. The disadvantage of SAW resonator generators is a small frequency tuning due to the narrow-band property inherent in piezoelectric resonators due to the small resonance gap [Dvornikov A.A., Ogurtsov V.I., Utkin G.M. Stable generators with filters on surface acoustic waves. - M. Radio and Communications, 1983, p. 113]. This limits their use in devices where a wide frequency tuning is required. In addition, the tuning range of the generator on the SAW resonator may not be sufficient to compensate for temperature frequency deviations, which can be significantly larger than the tuning provided.

The closest to the construction of the generator to the claimed utility model is a generator on a SAW filter [Patent for utility model RU 104798 U1. Surfactant Generator. / Zavyalov S.A., Lyashuk A.N., Lepetaev A.N. - publ. 05/20/2011], made according to the three-point capacitive circuit, containing an amplifier on the transistor according to the scheme with a common collector between the common wire and the emitter, and also between the base and emitter of which phasing capacitors are connected, and a buffer amplifier is connected to the emitter of the transistor, and the input terminals of the SAW filter are connected between the base of the transistor and the common wire of the source, and the output terminals of the SAW filter are connected between the common wire and the first terminal of the inductance, to which the first terminal of the capacitor is connected, the second terminal of which It is connected to the common wire, to the second inductance terminal is connected a varicap cathode and a resistive voltage divider consisting of two series-connected resistances, while the first output of the first resistance is connected to the reference voltage, and the first output of the second resistance is connected to the second output of the first resistance, moreover, it the second terminal is connected to a common wire, while the first resistance terminal is connected to the common point of connections of the first and second resistances, the second terminal of which is connected to a varicap method, and a resistive-diode voltage divider consisting of a resistance, the reference voltage source is connected to its first output, while the first resistance output is connected to its second output, while its second output is connected to the varicap anode, and a chain of N is connected in series connected diodes, so that the anode of the previous diode is connected to the cathode of the next, while the cathode of the last in the diode chain is connected to a common wire, and the anode of the first diode in the chain is connected to the second resistance terminal of the resistive diode of the voltage divider.

An advantage in this generator based on a SAW filter is its extended frequency range for tuning the oscillator, covering the range of deviations of the generator frequency from the effects of temperature over a wide range of operating temperatures.

The disadvantage is the poor reproducibility of the nominal frequency of the generated oscillation, which is associated with a deviation of the parameters of the SAW filter from sample to sample and resistive-diode voltage dividers, as well as insufficient temperature stability of the frequency of the output oscillation.

The technical result of the utility model is to increase the accuracy of the installation and reproducibility of the nominal value of the frequency and increase the temperature stability of the frequency of the output oscillation.

The specified technical result is achieved by the fact that in a generator for a SAW containing an amplifier on a transistor according to the scheme with a common collector between the common wire and the emitter, and also between the base and emitter of which phasing capacitors are connected, and a buffer amplifier is connected to the emitter of the transistor, and the input terminals of the SAW the filter is connected between the base of the transistor and the common wire of the source, and the output terminals of the SAW filter are connected between the common wire and the first output of the inductance, according to the claimed technical solution, additional The resistor, capacitor, varicap, the anode of which is connected to the common wire, and the cathode to the first inductance terminal, the second terminal of which is connected to the first output of the capacitor and the first output of the resistor, the second terminal of the capacitor is connected to the common wire, and the temperature sensor, analog-to-digital converter, processor, first and second digital-to-analog converter with current output, current-to-voltage converter so that the output of the current-to-voltage converter is connected to the second terminal the resistor, and the outputs of the first and second digital-to-analog converter with a current output are connected to the input of the current-to-voltage converter, each input of which is connected to the first and second output of the processor, which has four inputs - the first, second and third inputs for programming the processor, to the fourth the input is connected to the output of an analog-to-digital converter, to the input of which the output of the temperature sensor is connected.

The essence of the utility model is illustrated by the drawing (Fig. 1), which shows a diagram of the proposed SAW generator with discrete temperature compensation and frequency correction, explaining the principle of its operation.

The generator on the SAW filter contains an amplifier on the transistor according to the scheme with a common collector 1 between the common wire and the emitter, and also between the base and emitter of which phasing capacitors 2, 3 are connected, and a buffer amplifier 4 is connected to the emitter of the transistor 4. Between the base of the transistor and the common source bus the input terminals of the SAW filter 5 are turned on, and the output terminals of the SAW filter 5 are connected between the common bus and the input of the P-circuit 6 containing the capacitor 7, inductance 8, varicap 9. The connection of the first output of the capacitor 7, the second output of which connected to the common wire, and the first output of the inductance 8, the second output of which is connected to the cathode of the varicap 9, the anode of which is connected to the common wire, form the input of the P-circuit 6, and the connection of the second output of the inductance 8 and the cathode of the varicap 9 - the input of the P-circuit 6 The output of the current-to-voltage converter 11 is connected to the cathode of the varicap 9 through the decoupling resistance 10 and the inductance 8. The varicap 9 (control capacitance) receives a control voltage from the converter 11 to compensate for temperature temperature drift and frequency correction. The control voltage generated in the converter 11 depends on the sum of the currents received from the digital-to-analog converters (DACs) with current outputs 12 and 13. At the same time, a control code is supplied to the DAC 12 from the processor 14, the value of which depends on the temperature, and on the DAC 13, a frequency correction code is received from processor 14. The value of the correction code depends on the value of the processor installed and stored in the memory using three external outputs: one for increasing, one for decreasing, and a third for writing the code stored in the processor memory. The value of the control code depends on the code coming from the analog-to-digital Converter 15, in which the conversion of the thermally dependent signal. The temperature-dependent signal comes from the temperature sensor 16, which is located so that between the temperature sensor 16 and the SAW filter 5, the temperature difference was the minimum possible.

A SAW generator with discrete temperature compensation and frequency correction operates as follows. The phase balance in the generator constructed according to the three-point capacitive scheme is performed when a SAW filter is connected between the base and the common wire (the collector of the transistor for alternating current is connected to the common wire), since the SAW filter in the passband has an inductive reaction. Connecting a matching U-shaped circuit containing a varicap to the SAW filter allows you to change the magnitude of the inductive reaction by applying a control voltage to the varicap. The amplitude balance is ensured by the amplifying and nonlinear properties of the transistor. In accordance with the set code in the processor memory (a value that depends on the nominal frequency value and a SAW filter sample) and in accordance with another code (a value that depends on the temperature in the generator and enters the processor after analog-to-digital conversion of the signal from the sensor temperature), the processor controls two digital-to-analog converters with current outputs. The output currents of the DAC are added and fed into the current transducer into voltage. Thus obtained, the voltage is the control for the varicap included in the matching P-circuit. The temperature compensation of the generator on the SAW filter is achieved by creating a temperature-dependent control action through the P-loop varicap on the SAW filter to regulate its reactance on the side of the transistor capacitive three-point generator circuit and thereby reduce the deviation of the generator frequency from the specified nominal value over a wide range of changes ambient temperature.

The positive effect of the proposed solution is the ability to control the value of the output frequency of the generator and improve the accuracy of temperature compensation. Improving the accuracy of the installation and reproducibility of the nominal frequency of the generator is achieved by using two DACs with a current output. In the process of setting the temperature compensation of the generator, the DAC output intended for setting and correcting the value receives a current corresponding to the code stored in the processor memory, which, in turn, is not equal to the extreme values corresponding to the DAC bit depth, but at least differs from them a value sufficient to correct long-term frequency drifts and sufficient to adjust the frequency to the nominal value, taking into account the spread in the parameters of the SAW filter. At the same time, the second DAC with current output, used for temperature compensation of generator frequency drift, works in the full range of codes, which increases the accuracy of temperature compensation, since in this case the minimum frequency tuning interval of the generator from changing the code by one can be reduced. The code corresponding to the temperature-dependent control of the generator can be generated in the processor in various ways, for example, the values of the codes can be calculated by the codes coming from the ADC, using an equation depending on the temperature-frequency characteristics of the generator on the SAW filter or can be extracted from the processor memory at the addresses depending on the codes coming from the ADC. In this case, the values of the codes generated by the ADC depend on temperature. The type of equation or an array of codes stored in the memory is determined at the stage of setting the temperature compensation of the generator.

A generator based on a SAW filter (Fig. 1) was implemented using ring SAW filters with low losses on a LiNbO3 crystal with a YX / 49 ° cut with a central frequency bandwidth of 200 MHz. The temperature stability of the generator on a SAW filter without the use of thermal compensation in the temperature range from minus 50 ° C to plus 90 ° is about 2 MHz or ± 5000 ppm. The practically realized value of the temperature stability of the generator on a SAW filter with the proposed discrete thermal compensation in the temperature range from minus 50 ° C to plus 90 ° C was ± 50 ppm, which is 2 orders of magnitude better. The accuracy of setting the nominal value is not worse than ± 2.5 ppm when using 12-bit ADCs.

Claims (1)

A SAW generator with discrete temperature compensation and frequency correction, containing an amplifier on a transistor according to the scheme with a common collector between the common wire and the emitter, and also between the base and emitter of which phasing capacitors are connected, and a buffer amplifier is connected to the emitter of the transistor, and the input terminals of the SAW filter are connected between the base of the transistor and the common wire of the source, and the output terminals of the SAW filter are connected between the common wire and the first output of the inductance, characterized in that a resistor is introduced into the circuit a torus, a capacitor, a varicap, the anode of which is connected to a common wire, and the cathode is connected to the first terminal of the inductance, the second terminal of which is connected to the first terminal of the capacitor and the first terminal of the resistor, and the second terminal of the capacitor is connected to the common wire, and the following nodes are introduced: temperature sensor , analog-to-digital converter, processor, first and second digital-to-analog converter with current output, current-to-voltage converter so that the output of the current-to-voltage converter is connected to the second output of the resistor RA, and the outputs of the first and second digital-to-analog converters with a current output are connected to the input of the current-to-voltage converter, each input of which is connected to the first and second output of the processor, which has four inputs - the first, second, and third inputs for programming the processor, and the fourth input is connected the output of an analog-to-digital converter, to the input of which the output of the temperature sensor is connected.