RU109622U1 - ANTENNA CONSENTING DEVICE - Google Patents

Abstract

 An antenna matching device containing a matching circuit formed by elements of three or four reactivity stores, a switch connected to the input of the matching circuit by the first output, a calibration resistor connected to the second output of the switch, a current transformer connected to the second output of the primary winding to the second input of the switch, a synthesizer frequencies, the first and second analog-to-code converters connected by synchronization inputs to the second output of the frequency synthesizer, a microcontroller connected by outputs the first port of the parallel interface to the corresponding control inputs of the switch and the matching circuit and connected by the second port of the serial interface to the control port of the frequency synthesizer, the first and second random access memory devices connected by digital outputs to the corresponding inputs of the second port of the parallel interface of the microcontroller, in which the first input of the switch and the output the matching circuit are respectively the RF input and the RF output, and the remote control port is microcontroller serial interface port, characterized in that a wide-band amplifier with adjustable gain is inserted into it, connected between the first output of the frequency synthesizer and the first output of the primary winding of the current transformer and connected to the third port of the serial interface of the microcontroller, the first and second low-pass filters connected respectively between the first output of the primary winding and the output of the current transformer and the analog inputs of the first and second

Description

The utility model relates to radio communication technology and can be used in wide-band radio transmitters to compensate for deviations of the input impedance of the antenna from the value at which the optimal operation mode of the radio transmitter power amplifier is ensured.

Closest to the proposed device is an antenna matching device [1], the circuit of which is shown in Figure 1. The antenna matching device contains a matching circuit formed by elements of four reactivity stores, a switch connected to the input of the matching circuit by the first output, an attenuator, a current transformer, connected by the first output of the primary winding to the attenuator output, and by the second output of the primary winding - to the second input of the switch, the microcontroller connected to the outputs of the first port of the parallel interface to the corresponding control inputs of the switch and the matching circuit, the first and second differential amplifiers connected by inputs to the attenuator output and the current transformer output, the first and second analog-to-digital converters connected by analog inputs respectively to the outputs of the differential amplifiers, the first and the second random access memory connected by inputs to the digital outputs of the analog-to-digital converters, respectively, and outputs to the second parallel port interface of the microcontroller, a calibration resistor connected to the second output of the switch, a frequency synthesizer connected by the first output to the input of the attenuator, the second output to the synchronization inputs of the analog-to-digital converters, and the control port to the third port of the serial interface of the microcontroller, the first input the switch and the output of the matching circuit are respectively the RF input and RF output of the device, and the first port of the serial interface of the microcontroller is the remote Foot control device.

Compensation of deviations of the input impedance of the antenna at a given operating frequency is carried out by switching between the output of the power amplifier of the radio transmitter and the antenna input of the corresponding reactive elements in the matching circuit of the device.

To determine the current impedance parameters of the “matching loop-antenna” path and the parameters of the switched reactivities, a measuring signal is supplied to the path in the form of an oscillation with a constant amplitude and a given frequency, and a set of samples proportional to the instantaneous voltage and current values at the path input is set and processed according to a certain algorithm .

In the device in question, the setup procedure may fail due to the influence of the signals of neighboring radio transmitters induced in the antenna with levels commensurate with the level of the measuring signal. To reduce the likelihood of a setup procedure failure under the influence of signals from neighboring transmitters, it is necessary that the level of the analog signal at the inputs of the analog-to-code converters does not exceed the voltage of their full discharge grid, and the frequency band of the paths for obtaining an array of samples does not exceed the value of the expected detuning in frequency of neighboring signals radio transmitters.

The objective of the utility model is the implementation in the antenna-matching device of the above requirements.

This object is achieved by the fact that in the antenna matching device containing the matching circuit formed by the elements of three or four reactivity stores, a switch connected to the input of the matching circuit by the first output, a calibration resistor connected to the second output of the switch, and a current transformer connected to the second output of the primary windings to the second input of the switch, a frequency synthesizer, the first and second analog-to-code converters connected by synchronization inputs to the second output of the synthesizer often t, a microcontroller connected by the outputs of the first port of the parallel interface to the corresponding control inputs of the switch and the matching circuit and connected by the second port of the serial interface to the control port of the frequency synthesizer, the first and second random access memory devices connected by digital outputs to the corresponding inputs of the second port of the parallel interface of the microcontroller, where the first input of the switch and the output of the matching circuit are respectively the RF input and RF output, and then The remote control om is the first port of the serial interface of the microcontroller, a broadband amplifier with adjustable gain is introduced, connected between the first output of the frequency synthesizer and the first output of the primary winding of the current transformer and connected to the third port of the serial interface of the microcontroller, the first and second low-pass filters included respectively, between the first output of the primary winding and the output of the current transformer and the analog inputs of of the first and second analog-to-code converters, the first and second frequency converters connected by the first digital inputs to the digital inputs of the analog-to-analog converters and connected by the second digital inputs to the digital output of the frequency synthesizer, the first and second digital filters connected by digital inputs respectively, to the digital outputs of the frequency converters and connected by digital outputs, respectively, to the digital inputs of random access memory, and the second digital outputs convert The analog-code lei are connected respectively to the inputs of the third port of the parallel interface of the microcontroller.

The figure 1 shows a prototype device containing, matching circuit 12 formed by elements of four reactivity stores, a switch 7 connected to the input of the matching circuit by the first output, attenuator 2, current transformer 8 connected to the attenuator output by the first output of the primary winding, and the primary output by the second output windings - to the second input of the switch, microcontroller 6, connected by the outputs of the first port of the parallel interface to the corresponding control inputs of the switch and matching circuit, the first 3 and W 9 different differential amplifiers connected by inputs to the attenuator output and current transformer output, first 4 and second 10 analog-to-digital converters connected by analog inputs respectively to the outputs of differential amplifiers, the first 5 and second 11 random access memory connected by inputs, respectively to the digital outputs of the analog-to-digital converters, and the outputs to the second port of the parallel interface of the microcontroller, a calibration resistor 13 connected to the second output to mmutator, frequency synthesizer 1, connected by the first output to the input of the attenuator, the second output to the synchronization inputs of the analog-to-digital converters, and the control port to the third port of the serial interface of the microcontroller, the first input of the switch and the output of the matching circuit are respectively the RF input and The RF output of the device, and the first port of the serial interface of the microcontroller is the remote control port of the device.

Figure 2 presents the proposed device containing a matching circuit 16 formed by elements of three or four reactivity magazines, a switch 9 connected to the input of the matching circuit by the first output, a calibration resistor 17 connected to the second output of the switch, a broadband amplifier with adjustable gain 2, a transformer current 10, turned on by the primary winding between the output of the broadband amplifier and the second input of the switch, frequency synthesizer 1, connected by the first output to the input of the wide amplifier, the first 3 and second 11 low-pass filters connected by inputs to the output of the broadband amplifier and the output of the current transformer, the first 4 and second 12 analog-to-code converters connected by analog inputs respectively to the outputs of the low-pass filters and connected by synchronization inputs to the second output of the frequency synthesizer, the first 5 and second 13 frequency converters connected by the first digital inputs respectively to the digital outputs of the analog-to-code converters and connected by the second by the front inputs to the digital output of the frequency synthesizer, the first 6 and second 14 digital filters connected by digital inputs respectively to the digital outputs of the frequency converters, the first 7 and second 15 random access memory devices connected by the digital inputs respectively to the digital outputs of the digital filters, microcontroller 8 connected to the second and third ports of the serial interface, respectively, to the control ports of the frequency synthesizer and broadband amplifier and connected to the outputs of the first and second ports parallel interface, respectively, to the control inputs of the switch and the matching circuit and the digital output of random access memory, the first input of the switch and the output of the matching circuit are respectively the RF input and RF output of the device, the first port of the serial interface of the microcontroller is the remote control port of the device, and the inputs of the third port the microcontroller’s parallel interface are connected respectively to the second digital outputs of the analog-to-code converters.

The proposed technical solution meets the criterion of "novelty" because differs from the prototype in the presence of new functional elements and new relationships between the elements.

Compensation of deviations of the input impedance of the antenna from acceptable values is carried out by connecting between the input of the power amplifier and the input of the antenna-feeder path the corresponding elements from the stores of the matching circuit, which contains one store of capacitors and two stores of inductor coils or one store of inductor coils and three store capacitors.

To tune the device to a given operating frequency, the initial values of the characteristics of the input impedance of the antenna-feeder path are first determined. To do this, the calibration resistor 17 or the input of the matching circuit 16, which at this time is connected via the RF output of the device directly to the input of the antenna-feeder path, are alternately connected to the first output of the frequency synthesizer 1 through an amplifier 2, a current transformer 10, and a switch 9. The frequency of the signal at the first output of the frequency synthesizer (test signal) is set equal to the specified operating frequency f _p . The frequency of the signal at the second output of the frequency synthesizer f _{on is} slightly higher than the maximum frequency of the operating frequency range. The analog-to-code converters 4 and 12 with a frequency of f _on read out the instantaneous values of the signals proportional to the voltage and current at the input of the matching circuit and at the calibration resistor. The frequency band of the signals at the analog inputs of the analog-to-code converters by low-pass filters 3 and 11 is limited by the frequency f _on , and their levels are automatically kept within the specified limits by adjusting the gain of amplifier 2 according to the readings of the second outputs of these converters. In converters 4 and 12, the obtained samples (samples) are multiplied with oscillation samples with a frequency f _p -Δf supplied to the second inputs of the converters from the digital output of the synthesizer. As a result of this, the test signal with a frequency f _p at the converter output will correspond to signals with a frequency Δf, the contribution of which in the samples taken from the outputs of digital filters 6 and 14, significantly exceeds the contributions of the signals of neighboring radio transmitters. The digital decimation filters used procedure, in connection with which the repetition frequency of samples at their outputs _O f does not exceed 100Δf. In random access memory devices 7 and 15, four arrays of samples corresponding to currents and voltages at the calibration resistor and at the input of the antenna-feeder path, which are used in the microcontroller 8 to calculate the values of active R _a and reactive X _a components of the complex input resistance of the antenna-feeder path according to the formulas

Here:

R _K is the resistance of the calibration resistor;

U, U _K , I, I _K are the values of the maximum samples in arrays corresponding to voltages and currents at the input of the matching circuit and at the calibration resistor;

I ₁ - values of the sample corresponding to the current at the input of the matching circuit, coinciding with the sample corresponding to the voltage, the value of which is minimally different from the previous one. and more

The obtained values of R _a and X _a must ensure the fulfillment of the inequality

where C is the minimum allowable value of the KBV load of the power amplifier.

If this inequality is not satisfied, the required reactance value of the matching circuit is calculated, for example, as indicated in [1] for the four-store matching circuit.

In the proposed device KB range it is advisable to use large integrated circuits similar to integrated circuits of Analog Devices:

AD8321AR - a broadband amplifier with a controlled gain;

AD9248BSTZ - four-channel analog-to-code converter;

AD6624AABC - a four-channel digital receiving signal processor, containing in each channel a frequency converter with a frequency synthesizer and a three-stage digital filter;

AD9957BSVZ - frequency synthesizer;

ADSP-BF537BBCZ - microcontroller.

The use in the proposed device of automatic adjustment of the test signal level eliminates the possibility of limiting the signal at the digital outputs of the analog-to-code converters 4 and 12, which leads to distortions in the results of measuring the current and voltage at the input of the matching circuit 16 by a signal of a neighboring radio transmitter of any level, regardless of its frequency offset relative to the test signal.

Using digital filters 4 and 16 with the characteristics implemented in the AD6624AABC microcircuit, it is possible to obtain a distortion of the measurement results of no more than 1% at the level of the interfering signal equal to the level of the test signal and its detuning at a frequency of at least 50 kHz.

Thus, the task of protecting against the effects of interfering signals in the proposed device is achieved.

Information sources

1. Patent for the invention RU 2309491 C1

Claims (1)

An antenna matching device containing a matching circuit formed by elements of three or four reactivity stores, a switch connected to the input of the matching circuit by the first output, a calibration resistor connected to the second output of the switch, a current transformer connected to the second output of the primary winding to the second input of the switch, a synthesizer frequencies, the first and second analog-to-code converters connected by synchronization inputs to the second output of the frequency synthesizer, a microcontroller connected by outputs the first port of the parallel interface to the corresponding control inputs of the switch and the matching circuit and connected by the second port of the serial interface to the control port of the frequency synthesizer, the first and second random access memory devices connected by digital outputs to the corresponding inputs of the second port of the parallel interface of the microcontroller, in which the first input of the switch and the output the matching circuit are respectively the RF input and the RF output, and the remote control port is microcontroller serial interface port, characterized in that a wide-band amplifier with adjustable gain is inserted into it, connected between the first output of the frequency synthesizer and the first output of the primary winding of the current transformer and connected to the third port of the serial interface of the microcontroller, the first and second low-pass filters connected respectively between the first output of the primary winding and the output of the current transformer and the analog inputs of the first and second analog-to-code converters, first and second frequency converters connected by the first digital inputs respectively to the digital inputs of analog-code converters and connected by the second digital inputs to the digital output of the frequency synthesizer, the first and second digital filters connected by digital inputs, respectively, to the digital the outputs of the frequency converters and connected by digital outputs, respectively, to the digital inputs of random access memory, and the second digital outputs of the converters "analog-to "Are respectively connected to the inputs of the third parallel port of the microcontroller interface.