RU2792220C1 - Hf transmission path with antenna matching device - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: transmission path of the HF band with an antenna matching device of the HF band. The transmission path of the HF band with an antenna matching device additionally contains a second operating frequency generator, the fourth and fifth high frequency switching nodes, a computer and two loads equivalent to the antenna impedance in the HF band.

EFFECT: increasing the speed of operation of the HF band transmission path by reducing the total tuning time of the antenna matching device by pre-tuning it to the next operating frequency at a load equivalent to the resistance of the applied antenna in the HF band.

1 cl, 1 dwg, 1 tbl

Description

The invention relates to radio engineering, and, in particular, to the transmission path of the HF band with an antenna matching device of the HF band.

A known device used in the transmission path of the HF band, according to the method of matching the transmitting antenna-feeder path with the antenna using several discretely tunable antenna matching devices [1]. The calculation of the elements included in their composition is based on the method of pie charts.

The disadvantage of the device is that when operating in a wide frequency range, a large number of discrete elements are required, a complex algorithm for tuning to the operating frequency and, as a result, require large labor costs for tuning and adjustment during testing at the facility.

A device [2] is known, in which its parameters are automatically adjusted by selecting its elements.

However, the phase sensor of the radio signal, which eliminates ambiguity in the process of auto-tuning of the antenna matching device, has a low sensitivity with significant detuning of the oscillatory circuit. This is due to the large dynamic range of current changes in the matching circuit during detuning, especially with its high quality factor. This device is difficult to set up, which leads to great labor costs when adjusting and testing the antenna matching device at the facility.

A device for matching the transmitting antenna-feeder path with the HF antenna used in the transmitting path of the HF band [3] is known. In the device at the input signal of the HF range, the voltage level is measured in the adjacent shoulders of each link (out of two) of the connected matching circuit (SC) and compared using comparing devices with each other. If the voltage in the left arm U(i) is less than the voltage in the right arm U(i+1) by a value greater than the insensitivity level of the comparing device, then the capacitances C21, C31 are switched off by means of the control device on the left arm and the capacitance C11=C1(min) is connected . If the voltage in the left arm is greater than the voltage in the right arm by a value greater than the dead level of the comparing device, then the capacitances C11, C21 are switched off by means of the control device on the left arm and the capacitance C31=C1(max) is connected. If the voltages in adjacent arms are equal or differ by an amount less than the deadweight level of the comparator, only one capacitance C21=C1(0) is connected to the left arm. For the second U-shaped link, all procedures are identical to those described above, only connect or disconnect containers C12, C22, C32. Comparison of voltage levels is carried out in the comparators of the control device, some of which have a negative threshold U(i)<U(i+1), part - positive U(i)>U(i+1). The results of the voltage comparison in the control device are converted into the corresponding voltages, which are fed through the output stages to the switching nodes consisting of HF switches, for example, relays, and in accordance with the algorithm described above, capacitors are switched and the device is tuned to each specific frequency within the operating frequency range.

The antenna matching device that implements this method is made on the basis of two distributed-type matching circuits on lumped elements switched by two relays, one of which is connected to the high-frequency input of the matching circuit, and the other to the high-frequency output of the matching circuit. In each of the inductance circuits are connected in series, and several capacitors are connected in parallel between them. Capacitors are switched using relays controlled by signals from the control device according to a given algorithm based on a comparison of voltages on adjacent links of the device.

The disadvantages of the analogue should include the fact that the switching of capacities in the matching circuit is carried out using high-frequency relays, carried out in several consecutive operations. The switching time of each high-frequency relay is several milliseconds, which in total can be several tens of milliseconds, which is much longer than the requirements for modern antenna matching devices operating in communication systems with pseudo-random frequency hopping for operation in fading channels. Therefore, such a device is not suitable for operation in some modes, for example, with pseudo-random frequency tuning.

Known antenna matching device transmitting antenna-feeder path with a HF antenna used in the transmitting path of the HF band, which by most essential features coincides with the proposed invention and is taken as a prototype [4]. It is made on the basis of the first matching circuit, in which the inductances are connected in series, and three capacitances are connected in parallel between them C1(i)=C1(min), C2(i)=C(0), C3(i)=C(max ) with the possibility of their connection using a control device based on a comparison according to a given algorithm of voltages on adjacent arms of each link of the matching circuit. This procedure is carried out in the input elements of the control device, which have a negative threshold for connecting capacitances C1(i) and C2(i) and a positive threshold for connecting capacitance C3(i). A broadband matching circuit (BSC) is connected to the output of the last link. The signal receiver of the global navigation satellite systems with an antenna and the program recording unit with an external input are connected by two-way connections to the corresponding inputs/outputs of the control device. The output of the operating frequency generator is connected to the input of the third high-frequency switching node, and the control input of the third high-frequency switching node is connected to the first control output of the control device. The first output of the third high-frequency switching node is connected to the first output of the first high-frequency switching node and to the input of the first matching circuit, and its second output is connected to the second output of the first high-frequency switching node and to the input of the second matching circuit. Moreover, in the case when, on command from the control device, the output of the first high-frequency switching node is connected to the first matching circuit, the second output of the third high-frequency switching node is connected to the second matching circuit. In the next communication session, the transmitting RF cable is connected to the second matching circuit through the first high-frequency switching node, and the operating frequency generator is connected to the first matching circuit through the third high-frequency switching node. The device includes a control panel, the output of which is connected to the input of the program recording unit, the second matching circuit, similar to the first one, as well as the first one, are connected using buses similar to the buses for controlling high-frequency switching nodes and monitoring voltage on neighboring links of the first and second nodes for connecting capacities and voltage control at the boundaries L, C of the first and second matching circuits, respectively. These buses are connected to the corresponding inputs/outputs of the control device. The inputs of the two matching circuits are connected to the transmission radio frequency cable by means of the first high-frequency switching node in the presence of a command from the second control output of the control device. The second matching circuit is connected through the second broadband matching circuit to the second input of the second high-frequency switching node, the output of which is connected to the antenna via an antenna RF cable. The third and fourth inputs/outputs of the control device are connected by two-way connections via buses for controlling switching nodes and monitoring voltage at neighboring links of the first and second matching circuits with the corresponding inputs/outputs of the first and second broadband matching circuits. The output of the second broadband matching circuit is connected to the second input of the second high-frequency switching node. The third control output of the control device is connected to the control input of the second high-frequency switching node. The input of the control device is used to select the type of connected antennas. The external input of the program recorder is the input of the device.

The disadvantages of the prototype include the fact that due to setting the second channel to a load that is not consistent with the antenna, when connected to a real antenna in the next session, it again has to be adjusted, which takes additional time. In addition, when preparing one of the branches for the next sending of a radio signal on the air, the characteristics of the antenna radio frequency cable, which introduce distortions into the shape of the transmitted radio signal during its actual transmission to the antenna, are not taken into account.

The purpose of the invention is to increase the speed of the HF transmitting path by reducing the total tuning time of the antenna matching device by pre-tuning it to the next operating frequency at a load equivalent to the resistance of the applied antenna in the HF range.

These technical results are achieved by the fact that in the HF transmission path with an antenna matching device, made on the basis of the first and second matching circuits and containing a signal receiver of global navigation satellite systems with an antenna and a program recording unit with an external input, connected by two-way connections to the corresponding inputs / outputs of the control device, the control panel, the output of which is connected to the corresponding input of the program recorder, the first operating frequency generator, the output of which is connected to the input of the third high-frequency switching node, and the control input of the first operating frequency generator is connected to the first control output of the control device, the control input of the third of the high-frequency switching node is connected to the second control output of the control device, the first output of the third high-frequency switching node is connected to the first output of the first high-frequency switching node and to the input of the first th matching circuit, and the second output - to the second output of the first high-frequency switching node and to the input of the second matching circuit, and in the case when, at the command from the control device, the transmitting RF cable is connected to the first matching circuit through the output of the first high-frequency switching node, the second output of the third high-frequency switching node is connected to the second matching circuit, and in the case when the transmitting RF cable is connected to the second matching circuit by command from the control device through the first high-frequency switching node, the first operating frequency generator is connected to the first matching circuit through the third high-frequency switching node, the device control is connected by two-way connections via control buses with high-frequency switching nodes and voltage control on neighboring links of the first and second matching circuits with the corresponding inputs/outputs of the first and of the second matching circuits, the inputs of the first and second matching circuits are connected to the transmitting radio frequency cable by means of the first high-frequency switching node on command from the second control output of the control device, the first and second matching circuits through the first and second broadband matching circuits are respectively connected to the first and second inputs of the second high-frequency switching node, the output of which is connected via an antenna RF cable to the antenna, the control device is connected by two-way connections with the corresponding inputs / outputs of the first and second broadband matching circuits, the third control output of the control device is connected to the control input of the second high-frequency switching node, while in each matching the inductance circuit are connected in series, and three capacitances C1(i)=C1(min), C2(i)=C(0), C3(i)=C(max) are connected in parallel between them with the possibility of their connection using a device control circuit based on a comparison according to a given algorithm of voltages on adjacent arms of each link of the matching circuit, which is carried out in the input elements of the control device, which have a negative response threshold for connecting capacitances C1(i) and C2(i) and a positive response threshold for connecting capacitance C3( i), while the first broadband matching circuit (BSC) is connected to the output of the last link of the first matching circuit, the second broadband matching circuit is connected to the output of the last link of the second matching circuit, and the control device has an input for selecting a program corresponding to the type of connected antenna, an external input the program recording block is the input of the device, additionally introduced the second operating frequency generator, the fourth and fifth high-frequency switching nodes, the calculator connected by two-way connections with the control device, the first and second operating frequency generators, a modulator combined with a power amplifier In this case, the high-frequency output of the modulator is connected to the input of the first high-frequency switching node through a transmitting radio-frequency cable, the first input of the modulator is connected to the high-frequency output of the second operating frequency generator, and the second input of the modulator is low-frequency, the control inputs of the fourth and fifth high-frequency switching nodes are connected to the third control output of the control device, the first matching circuit is connected through the first broadband matching circuit to the first input of the fourth high-frequency switching node, and the first load equivalent to the antenna impedance in the HF band is connected to the second input of the fourth high-frequency switching node through the first RF cable, the second matching circuit is connected through the second broadband the matching circuit is connected to the first input of the fifth high-frequency switching node, and to the second input of the fifth high-frequency switching node through the second radio frequency The second load equivalent to the antenna impedance in the HF band is connected to the second cable, and in the case when the first matching circuit through the first broadband matching circuit, the fourth and second high-frequency switching nodes are connected to the RF antenna cable, the second matching circuit through the second broadband matching circuit, the fifth the high-frequency switching node and the second RF cable are connected to the second load, equivalent to the antenna impedance in the HF band, in the next communication session, when the second broadband matching circuit through the second broadband matching circuit, the fifth and second high-frequency switching nodes are connected to the antenna RF cable, the first broadband matching the circuit through the fourth high-frequency switching node and the first radio-frequency cable is connected to the first load, equivalent to the antenna impedance in the HF band, while the receiver of global navigation signals These satellite systems with an antenna have an output for synchronization of the calculator, and the calculator has an input for synchronization and an input for entering operating modes, the length and brand of the first and second RF cables are similar to the length and brand of the RF antenna cable.

The figure 1 shows a block diagram of the antenna matching device, where the designations are introduced:

1, 4 - the first and second nodes for connecting capacitances and controlling voltages at the boundaries L, C of the links that are located at the junction point of the beginning and end of the inductances in the first and second matching circuits 12 and 13;

2 - control device;

3, 5 - the first and second broadband matching circuits;

6, 7 - transmitting and antenna RF cables;

8, 9 and 21 - the first, second and third high-frequency switching nodes;

10 - connected antenna;

11 - input of control device 2 for selecting a program for the type of connected antennas;

14 - receiver of signals of global navigation satellite systems with an antenna;

15 - block recording programs with an external input 17;

16 - control panel;

18 and 19 - tires for controlling high-frequency switching nodes and monitoring voltage on neighboring links of the first and second matching circuits 12 and 13, respectively;

20 - the first generator of the operating frequency;

22 - the second generator of the operating frequency;

23 - modulator combined with a power amplifier;

24 - input for entering the operating modes of the calculator 34;

25 - output of the receiver 14 signals of global navigation satellite systems for synchronization of the calculator 34;

26 - low-frequency input of node 23;

27 - synchronization input of the calculator 34;

28 and 29 - the fourth and fifth high-frequency switching nodes;

30 and 31 - the first and second RF cables;

32 and 33 - the first and second loads, equivalent to the resistance of the antenna in the HF band;

34 - calculator.

L1(i) and L2(i) are the inductances of the i-th link of the first and second circuits of the matching device.

The capacitances of the first and second matching circuits have different ratings, since they are tuned to different frequencies:

C11(i)=C11(i+1)=C1(min), C21(i)=C21(i+1)=C1(0),

C31(i)=C31(i+1)=C1(max),

C12(i)=C12(i+1)=C2(min), C22(i)=C22(i+1)=C2(0),

C32(i)=C32(i+1)=C2(max).

These equalities are true for all parts of the device.

Before starting the matching procedure, the characteristics of all possible types of antennas 10 are measured or they are taken from the specifications. Then determine the nature of the reactivity and other characteristics of the connected antenna (inductive or capacitive). All data necessary for the manufacture and adjustment of the loads 32 and 33 are recorded in the memory of the control device 2. The complexity of building loads 32 and 33 determines the quality of equivalence (coincidence) of their characteristics with the characteristics of a real antenna 10, the more complex the design of the loads, the better the match and less time is required for additional adjustment of the antenna matching device, which reduces the preparation time for the next session. Depending on the nature of the reactivity of the connected antenna, a control command from the calculator 34 through the control device 2 in accordance with the program recorded through the input 24 connects the first or second matching circuits 12 or 13 through the first or third high-frequency switching nodes 8 and 21 to the output of the modulator 23, combined with power amplifier, or the output of the first generator 20 operating frequency, respectively. The setting begins with the selection of the initial data from the memory of the control device 2 by applying to the input 11 of the appropriate command, one of several. Coordination starts with the corresponding first or second matching circuit 12 or 13, depending on the position of the first and third high-frequency switching nodes 8 and 34. This setting is necessary to compensate for the reactive component and increase the traveling wave ratio (TWR) of the antenna matching devices. Next, adjust the parameters of the second L, C link of the connected matching circuit using nodes 2, 19 or 18, 4, closest to the antenna, and then proceed to setting the first L, C link. To ensure electromagnetic compatibility and further increase the ICF, the case of the input RF cable is connected to the signal cases of the first and second matching circuits 12 and 13, and the antenna (output) RF cable 7 is connected to the antenna 10. For each matching circuit 12 and 13, the initial capacitance C1(i ), inductance L1(i) and the magnitude of the change in capacitance AC(i) of each link of the low-pass filter on L, C elements are selected according to known formulas [5-8].

Connecting additional containers during automatic tuning of each circuit is carried out using the calculator 34 through the control device 2 according to the following algorithm. If the voltages measured using analog-to-digital converters (ADC) in the control device 2 at the outputs of the control and monitoring bus 18 or 19 at the boundaries of adjacent links differ from each other less than by the value determined by the price of the low-order digit of the ADC, then the capacitance C( i) does not change its value. If the voltage on the previous link is greater than in the next one, then it is necessary to connect the capacitance C(i) of the maximum value, otherwise the capacitance C(i) of the minimum value is connected. The high-frequency input of the modulator 23, combined with the power amplifier, is supplied with a highly stable carrier frequency from the second generator 22 of the operating frequency. The transmitted information is fed to the low-frequency input 26 of the modulator 23 combined with the power amplifier.

To configure a currently idle chain consisting of serially connected nodes 13 and 5 or 12 and 3, the first operating frequency generator 20, the third high-frequency switching node 21, the control device 2, buses 18 or 19 are used. The basis of the first and second operating frequency generators 20 , 22 is a highly stable reference frequency generator (frequency synthesizer), made, for example, on a thermally stabilized quartz oscillator. The division coefficients in the operating frequency generators are selected so that its operating points would cover the entire set of frequencies, the denominations and the sequence of installation in time of which are entered from the calculator 34 or at the input 17 or from the control panel 16 when writing the communication plan to block 15. frequency is necessary to tune currently idle nodes 13 and 5 or 12 and 3 to the frequency that will be in the next (in time) session (time interval). To implement this procedure, the output of the first generator 20 of the operating frequency is connected to the input of the third high-frequency switching node 21, the control input of which is connected to the second control output of the control device 2. The first output of the third high-frequency switching node 21 is connected to the first output of the first high-frequency switching node 8, and the second output is connected to the second output of the first high-frequency switching node 8. When a command is received from the calculator 34 through the control device 2 and the input of the first high-frequency switching node 8, the RF transmission cable 6 (antenna-feeder path) is connected to the first matching circuit 12, the input of the third high-frequency switching node 21 - to the second matching circuit 13. In the next communication session, the transmitting RF cable 6 through the first high-frequency switching node 8 is connected to the second matching circuit 13, and the generator 20 operating frequency through the third high-frequency switching node 21 - to the first matching circuit 12. So it continues until the end of the device. Setting the operating frequency for the next communication session using calculator 34 is carried out by a command supplied from control device 2, which is formed in accordance with the communication plan recorded in calculator 34 at input 24 and in block 15 at input 17.

The work of the path is explained by the table.

In the table, the “plus” sign marks the operations carried out to pass the radio signal transmitted over the air, and the “two pluses” sign marks the procedures for preparing the antenna matching device for working on the air at the next time point (in the next communication session).

High-frequency switching nodes 8, 9, 21, 28 and 29, depending on the commands coming from the calculator 34 through the control device 2, switch one of the two matching circuits 12 or 13, which is currently tuned to the operating frequency specified by software using calculator 34 through the control device 2 or from the program recorder 15 according to the initial data entered in advance at the inputs 24 or 17. At the same time, the other of the two matching circuits 12 or 13 is tuned to the next known operating frequency in accordance with the initial data entered in calculator 34 or block 15 in advance by inputs 24 or 17, which must be on the air for a specified time interval, synchronized with time stamps from the receiver 14 of signals of global navigation satellite systems with an antenna. To do this, use its output 25, the input 27 of the calculator 34 and two-way communication with the control unit 2.

After software switching in the next session of high-frequency switching nodes 8, 9, 21, 28 and 29, depending on the commands coming from the calculator 34, the matching circuit 12 or 13 is connected through the control device 2, which is already tuned to the operating frequency at the current time, set programmatically with the help of commands coming from the calculator 34 through the control device 2 or the program recording unit 15, and the other matching circuit 12 or 13, according to the initial data entered in advance at the inputs 24 or 17, begins to tune to the next operating frequency in time, and so on.

Antenna 10 is a circuit consisting of reactive and active components. Therefore, after the end of the radio pulse, a part of the energy remains in the circuit, which is interference for a new session (new frequency). To eliminate the interference, the calculator 34, after each radio pulse transmitted over the air, forms a guard interval with the duration necessary to reduce the interference to the required level. The generated sequence of pulses is controlled by the second generator 22 of the operating frequency. In the calculator 34, 2 programs work simultaneously: the first one is for generating and broadcasting a radio signal, the second one is for tuning the second branch of the antenna matching device to the next operating frequency. Moments of changing messages are synchronized in time, the sequence of changing frequencies and their value are known to all communication subscribers. With the help of two-way communications, the calculator 34 controls the performance of the respective nodes.

The first and second nodes 1 and 4 for connecting capacitances and monitoring voltages on the L, C links must be installed on both sides of the inductances to eliminate the parasitic effect of the currently inactive (disconnected) inductance.

When the frequency moves from the lower part of the HF range to the upper ratings of the capacitances, they should decrease. According to well-known methods [5-8], it is possible to select such capacitance ratings that they will allow covering the entire operating frequency band of the HF range. To do this, it is necessary to install in each arm of the low-pass filter (LPF) not 3 capacitances, as shown in the figure, but more than four capacitances, each with its own capacitance connection nodes. In the preliminary calculations programmed in the calculator 34 or in the control device 2, it is necessary to strive for the minimum number of capacities at which the requirements for the time of tuning the antenna matching device to a new operating frequency are met, for example, within a given time interval (current communication session), in order to fulfill the requirements for providing a given coefficient of the traveling wave at the exact given time, determined jointly by blocks 2, 14 and 15. It is also possible to improve the quality of matching by minimizing the length of the RF antenna cable 7.

During the passage of the radio signal in the setup mode, the voltage levels are alternately taken in the adjacent arms of each link of the connected matching circuit and compared using the ADC, located, for example, in the control device 2.

The purpose of the control device 2 is to control the connection of capacities in nodes 1 and 4, nodes 12, 13, 3, 5 using high-frequency switching nodes 8, 9, 21, 28 and 29 in accordance with the tuning algorithm and depending on the command for selecting the type of connected antennas at the input 11 of the control device 2 to ensure efficient operation of the device at all frequencies of the operating range, detection of transmitted radio signals, analog-to-digital conversion of the received video signals and comparison at the ADC outputs of the voltage levels at the ends of the inductances of the first and second matching circuits 12 and 13. The ADCs operate with positive and negative voltages. With a positive value obtained, an increase in the connected capacitance is carried out, with a negative value, a decrease in capacitance. Data on the measured parameters of the connected antennas and the corresponding operation algorithms are entered into the memory of the calculator 34 and the control device 2 (duplication is carried out to improve the reliability of the equipment). If necessary, the parameters of the new connected antennas and the new algorithm are entered into the calculator 34 and into the control device 2, the data of which are used when generating control commands for tuning to a new frequency in accordance with the initial data entered into the calculator 34 and block 15 via external inputs 24 and 17 respectively. The parallel inputs and outputs of the control device 2 are connected by two-way connections via control buses with high-frequency switching nodes 8, 9, 21, 28, 29 and voltage control buses on neighboring links 18 and 19 with the first and second nodes 1 and 4 for connecting capacities and monitoring voltages on L, With links of the first and second matching circuits 12 and 13. To obtain the required values of the KBV, for example, at least 0.8 at all operating frequencies of the HF band, the entire operating range is divided into at least three subbands, for example, (3-9) MHz , (9-15) MHz, (15-30) MHz, and automatically by the software method, in accordance with the operating modes stored in the memory of the calculator 34 and node 15, the first generator 20 generates the next operating frequency, and the corresponding circuit is tuned to it.

In one of the options for using the device, after it is installed on the object, test tests can be carried out, for example, according to the following method. By external inputs 24 or 17 from the technological computer, or to the calculator 34, or from the control panel 16 to the program recording unit 15, the ratings of the operating frequencies that will be used in the communication session are alternately entered. For each operating frequency, the control device 2 receives a command from the calculator 34 or from the program recording unit 15 to alternately adjust the links of the first and second matching circuits 12 and 13, respectively. From one of the outputs of the control device 2 to the first generator 20 of the operating frequency, a command is given by which the required frequency is set, and using the first, second, third, fourth and fifth high-frequency switching nodes 8, 21, 9, 28 and 29, the corresponding switching is carried out and, according to the previously discussed algorithm, the adjustment is made. As soon as the setting is completed, via the bus 18 for controlling high-frequency switching nodes or the bus 19 for monitoring the voltage on adjacent links of the first and second matching circuits 12 and 13, the control device 2 receives receipts about the status of all switches of the first or second nodes 1 or 4 for connecting containers and control voltages on L, C links located at the connection point of the beginning and end of the inductances in the first and second matching circuits 12 and 13. Receipts are then broadcast through the control unit 2 to the calculator 34 and to the program recording unit 15. The recorded monitoring data is used in operation to reduce the time it takes to tune the device to a new operating frequency.

Depending on the power level of the transmitted signal, capacitors of the K10-47 type and inductors on a PEV-2 wire without a core can be used as elements of the matching circuit 12 or 13. As switching elements, you can use, for example, high-frequency vacuum circuit breakers and switches manufactured by NIIEMP JSC (Penza, Russia) (for example, V1D-12 V polarized switches). The control device includes comparators, for example, 1401CA1, diodes (for detection) 2D522, transistors of the "Transistor matrix 2P7240BS9" type, the load of which is the relay winding. Control device 2 and program recording unit 15, calculator 34 can be implemented, for example, on a processor board 5066-586-133 MHz - 1 MB, 2 MB Flash CPU Card from Octagon Systems with the corresponding additional modules. The first and second nodes for connecting capacitances and controlling voltages on L, C links, high-speed switching nodes built on the basis of semiconductor electronic radio elements operating in a pulsed mode, using pin diodes as switching elements, which have a switching time of a few microseconds [8, 9], which makes it possible to ensure that the matching circuit is tuned to the next operating frequency in time during a communication session. Switching is carried out when an external constant bias voltage is applied to the pin diode [7–10]. The range of switching frequencies is from 0.2 to 18 GHz. Oscillators 20 and 22 can be made on serial synthesizers with thermally stabilized quartz. As node 23, serial modulators and HF power amplifiers can be used.

The transmission path of the HF range with an antenna matching device allows you to:

- work in a wide range of HF frequencies while reducing the influence of residual transients in the antenna after the end of the radio pulse;

- work with antennas of various types, both ground-based and aircraft, conformal, for example, slot, vibrator and others in various modes, including pseudo-random frequency hopping to combat fading in the radio channel;

- increase the efficiency of tuning the parameters of the antenna matching device by eliminating additional adjustment of its circuits at the start of a communication session, which became possible due to more accurate tuning of the circuits due to the introduction of additional radio-frequency cables and loads equivalent to the antenna resistance and the use of high-speed switching semiconductor elements built, for example, based on pin diodes that provide the required communication session time to adjust the second matching circuit to the next operating frequency.

Literature.

1. Vorobyov O.Ya., Kozin S.V. On the question of constructing a discretely tunable contour. // Issues of radio electronics, ser. Radio Communication Engineering, Vol. 5, 1970, pp. 48-54.

2. Author's certificate of the USSR No. 487447, published 10/05/1975.

3. Patent of the Russian Federation No. 2359402, published on 06/20/2009, Bull. No. 17.

4. Patent of the Russian Federation No. 2698507, published: 08/28/2019, Bull. No. 25 (prototype).

5. Designing radio transmitting devices using computers: Textbook for universities / O.V. Alekseev, A.A. Golovkov, A.Ya. Dmitriev and others; Ed. O.V. Alekseev. - M.: Radio and communication, 1987. - 392 p.

6. Filippovich G.A. Method of broadband impedance matching. "Radio engineering and electronics". Mn., Issue. 25, 2000, pp. 153-159.

7. Filippovich G.A. Synthesis of transfer functions for complex loads. "Physics of wave processes and radio engineering systems". Vol. 6, No. 1, 2003, pp. 73-76.

8. Filippovich G.A. Solvability of the constraint system in broadband matching problems. //Radio engineering devices and systems, 2003.

9. Physical foundations of a semiconductor diode in a pulsed mode. Nosov Yu.R. M.: Science. The main edition of physical and mathematical literature. 1968. 263 p. (Fig. 6.5. p. 212).

10. Switching RF and microwave signals using p-i-n-diodes. http//www.club155.ru Switchers-pin.

Claims (12)

The HF-range transmission path with an antenna matching device, made on the basis of the first and second matching circuits, containing a signal receiver of global navigation satellite systems with an antenna and a program recording unit with an external input, connected by two-way connections to the corresponding inputs/outputs of the control device, a control panel, the output of which is connected to the corresponding input of the program recording unit, the first operating frequency generator, the output of which is connected to the input of the third high-frequency switching unit, and the control input of the first operating frequency generator is connected to the first control output of the control device, the control input of the third high-frequency switching unit is connected to the second control output of the control device, the first output of the third high-frequency switching node is connected to the first output of the first high-frequency switching node and to the input of the first matching circuit, and the second output is connected to the second output at the first high-frequency switching node and to the input of the second matching circuit, moreover, in the case when, on command from the control device, the transmitting radio-frequency cable is connected to the first matching circuit through the output of the first high-frequency switching node, the second output of the third high-frequency switching node is connected to the second matching circuit, and in the case when the transmitting radio-frequency cable, on command from the device control through the first high-frequency switching node is connected to the second matching circuit, the first operating frequency generator is connected to the first matching circuit through the third high-frequency switching node, the control device is connected by two-way connections via control buses with high-frequency switching nodes and voltage control on neighboring links of the first and second matching circuits with the corresponding inputs/outputs of the first and second matching circuits, the inputs of the first and second matching circuits are connected to the RF transmission cable by means of the first high-frequency switching node on command from the second control output of the control device, the first and second matching circuits through the first and second broadband matching circuits are respectively connected to the first and second inputs of the second high-frequency switching unit, the output of which is connected via an antenna RF cable to the antenna, the control device is connected by two-way connections with the corresponding inputs/outputs of the first and second broadband matching circuits , the third control output of the control device is connected to the control input of the second high-frequency switching node, at the same time, in each matching circuit, the inductances are connected in series, and three capacitances are connected in parallel between them C1(i)=C1(min), C2(i)=C(0), C3(i)=C(max) with the possibility of their connection using a control device based on a comparison according to a given algorithm of voltages on adjacent arms of each link of the matching circuit, which is carried out in the input elements of the control device, which have a negative response threshold for connecting capacitances C1(i) and C2(i) and a positive response threshold for connection capacitance C3(i), while the first broadband matching circuit (BMC) is connected to the output of the last link of the first matching circuit, the second broadband matching circuit is connected to the output of the last link of the second matching circuit, and the control device has an input for selecting a program corresponding to the type of connected antenna, the external input of the program recorder is the input of the device, characterized in that it additionally includes a second operating frequency generator, a fourth and fifth high-frequency switching nodes, a calculator connected by two-way connections to the control device, the first and second operating frequency generators, a modulator combined with a power amplifier, while the high-frequency output of the modulator through the transmitting the radio frequency cable is connected to the input of the first high-frequency switching unit, the first input of the modulator is connected to the high-frequency output of the second operating frequency generator, and the second input of the modulator is low-frequency, the control inputs of the fourth and fifth high-frequency switching nodes are connected to the third control output of the control device, the first matching circuit is connected through the first broadband matching circuit to the first input of the fourth high-frequency switching node, and the first load equivalent to antenna resistance in the HF band, the second matching circuit is connected through the second broadband matching circuit to the first input of the fifth high-frequency switching node, and the second load is connected to the second input of the fifth high-frequency switching node through the second RF cable, which is equivalent to the antenna resistance in the HF band, moreover, in the case when the first matching circuit through the first broadband matching circuit, the fourth and second high-frequency switching nodes are connected to the antenna RF cable, the second matching circuit through the second broadband matching circuit, the fifth high-frequency switching node and the second RF cable is connected to a second load equivalent to antenna resistance in the HF band, in the next communication session, when the second broadband matching circuit through the second broadband matching circuit, the fifth and second high-frequency switching nodes are connected to the antenna RF cable, the first broadband matching circuit through the fourth high-frequency switching node and the first RF cable is connected to the first load, equivalent to the antenna resistance in HF band, in this case, the receiver of signals of global navigation satellite systems with an antenna has an output for synchronizing the calculator, and the calculator has an input for synchronization and an input for entering operating modes, the length and brand of the first and second radio frequency cables are similar to the length and brand of the antenna radio frequency cable.

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