RU2703998C1 - Signal-interference complex - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: invention relates to radio engineering and can be used to generate a signal-noise environment in the interest of substantiating characteristics and parameters of radioelectronic equipment (REE) for evaluating their electromagnetic compatibility and noise immunity. Signal-jamming complex comprises a receiving antenna, in series connected to a receiving-excitatory unit, which are located in the ground part of the device, and also comprises an unmanned aerial vehicle (UAV), which is an onboard part of the device, on which there are: on-board control device of micro-computer, as well as onboard flight controller and onboard UAV control device, interconnected, wherein ground part of device comprises ground control computer, first output of which is second input of receiving excitation unit, connected by output to its first input, second output of the ground-based control computer is the input of the microcomputer located in the ground part of the control device, which is connected via a radio channel to the on-board micro-computer control device, the third output of the ground-based control computer is the input of the UAV control device located in the ground part, which is connected via a radio channel to the on-board control device UAV, and the output of the third input of the ground-based control computer, also includes a test REE, as well as a UAV-arranged transceiving antenna connected via a radio channel to a receiving antenna located in close proximity to the phase center of the tested REE, and the REE under test, which output is input of receiver in series connected to demodulator, which output is second input of digital-analog formation of signal-to-noise ratio (DAF SNR) sub-module, which first output is input of receiving-transmitting antenna, and second output is input of on-board control device of micro-computer connected by its output to first input of submodule DAF SNR.

EFFECT: high quality and efficiency of substantiating REE parameters for evaluating their electromagnetic compatibility and noise immunity.

1 cl, 1 dwg

Description

The invention relates to radio engineering and can be used to form a signal-noise environment in the interests, for example, of substantiating the characteristics and parameters of electronic equipment (RES) to assess their electromagnetic compatibility and noise immunity.

To assess the quality of functioning of RESs for various purposes and justify the requirements for them regarding electromagnetic compatibility, noise immunity, as well as the requirements that ensure their protection from electromagnetic radiation (interference) of natural and artificial origin, it is necessary to create a signal-noise situation, which allows to: create a signal-noise situation the required (given) structure and complexity from various points of space; the formation of long-term tactical signal-jamming scenarios, as well as the possibility of operational and hardware-software control of the generated signal-jamming situation and maintaining its operational objective documentation.

At the same time, a high-quality solution to these problems is relevant, since the procedure for solving them is a rather time-consuming and technically complex process.

The achieved level of development of the manufactured simulation equipment and methods (mathematical, software, technical, technological, etc.) for the formation of various types and parameters of signals and noise based on its use, allows us to solve the above problems at completely different software, technical and technological levels. This can be achieved on the basis of the development of a signal-jamming complex, which allows to ensure: the formation of a signal-jamming situation of the required (given) structure and complexity from various points of space with reference to the coordinates and operating time of the devices (tested RES and RES forming the required (specified) signal -interference); the formation of long-term tactical signal-jamming scenarios in the interest of evaluating the characteristics and parameters of RES during their testing, as well as the possibility of operational and hardware-software control of the generated signal-jamming situation and conducting its operational objective documentation. The proposed complex will be able to solve a wide range of test and research problems as a part of systems and complexes of RES for various purposes, at all stages of the life of RES in the interest of assessing their electromagnetic compatibility, noise immunity and information capabilities.

A known device for the formation of radio interference / 1. Radio interference shaping device. - Patent for invention RU No. 2484590, H04K 3/00, 06/10/2013 /. The device comprises: a receiving antenna coupled in series, a receiving-exciting unit and a radio transmitting unit with a transmitting antenna, as well as a jamming unit and a control unit, as well as a permission block, a clock synchronization unit, a pseudo-random sequence generator and a radio suppression unit for convolutional communication channels. This device allows you to expand the functionality of the formation of radio interference in the suppression of lines (channels) of radio communication.

The disadvantage of this device is the lack of the ability to create the required signal-jamming environment by a mobile source of signals from various points in space with reference to the coordinates and operating time of the receiving and transmitting RES devices.

The closest in technical essence to the claimed invention is, adopted for the prototype, the complex formation of the signal-jamming environment 12. The complex of forming the signal-jamming situation. - Patent for invention RU No. 2626384, H04K 3/00, 07.26.2017 /. The device comprises: a receiving antenna connected in series with the receiving-excitation unit, which are located in the ground part of the device, as well as connected in series to a radio transmitting unit and a transmitting antenna, connected via a radio channel to a receiving antenna and located on an unmanned aerial vehicle (UAV), which is an onboard part a device that also houses a microcomputer, the first output of which is the input of the radio transmitting unit, the second output of the microcomputer is the input of the on-board devices micro-computer control, the output of which is its input, the UAV also has an on-board flight controller and an on-board UAV control device, interconnected with each other, while the ground part of the device contains a ground control computer, the first output of which is the second input of the excitatory unit connected the output with its first input, the second output of the ground control computer is the input located in the ground part of the micro-computer control device, connected via radio with the on-board control device ikro-computer, the third exit surface control computer is located in the entrance part of the UAV ground control unit connected by radio with the on-board drone control device, and output to the third input ground control computer.

The disadvantages of this complex of the formation of the signal-noise situation are: one or several algorithms for the formation of signals and noise in the radio transmitting unit that are hard-coded, as well as the inability to generate long-term (several) tactical signal-jamming scenarios for one UAV departure due to significant mass and size characteristics the on-board equipment placed on it, which does not allow the UAV to be in the air, the time required for their formation, and the possibility of operational (interactive but) algorithm change signal generating parameters and the results of the interference signal processing corresponding to the operation modes RES test in real time.

The objective of the invention is the hardware-software control of the formation of the required (given) signal-jamming situation (tactical scenarios) for the RES by a mobile source of signals (interference) from various points of space with reference to the coordinates and operating time of the test RES and RES forming the required (preset) signal interference environment and objective documentation of signal parameters, interference and the coordinate position of the RES of the signal source (interference).

The technical result that provides the solution of this problem is to improve the quality and efficiency of the justification of the parameters of radio electronic equipment to assess their electromagnetic compatibility and noise immunity due to the formation of long-term (several) tactical signal-jamming scenarios for one UAV flight due to a decrease in the mass-dimensional characteristics of the onboard equipment and operational (interactive) changes in the algorithm for generating parameters of signals and noise based on the account of the operating modes of the Washable RES in real time.

The specified task and the achievement of the claimed technical result are achieved due to the fact that in the known device containing the receiving antenna is connected in series with the receiving-excitation unit, which are located in the ground part of the device, as well as containing a UAV, which is the onboard part of the device on which: onboard a micro-computer control device, as well as an on-board flight controller and an on-board UAV control device, interconnected, while the ground part of the device contains there is a ground control computer, the first output of which is the second input of the receiving-excitation unit, connected by the output to its first input, the second output of the ground control computer is the input of the micro-computer control unit located in the ground part, connected via the radio channel to the on-board micro-computer control device , the third output of the ground control computer is the input of the UAV control device located in the ground part connected via the radio channel with the onboard control device of the UAV, and the output with the third input to emnoy control computer is inputted experienced RES based radar type P-18P / 3. Military technical training. Radar device RTV Air Force. Radar station P-18R: textbook .: at 2 hours. Part 1 / E.N. Garin, D.D. Dmitriev, V.N. Tyapkin et al .; ed. E.N. Garin. - Krasnoyarsk: Sib. Feder. Univ., 2012 /, located in close proximity to the receiving antenna of the ground part of the device, a transmitting and receiving antenna located on a UAV based on a log-periodic antenna of the AARONIA 9803/5 / 4 type. User manual AARONIA 9803/5. Germany, 2016 /, connected via a radio channel with a receiving antenna and a tested RES, the output of which is the input of a type / 5 receiver. Radio receivers Under. ed. Zhukovsky A.P. - M: Higher school, 1989, pp. 8-10 / sequentially associated with the type demodulator / 6. Plashkov V.V. Radio receivers - M: Radio and communications, 1984, pp. 12-14 /, the output of which is the second input of the sub-module of the digital-to-analog formation (CAF) of the signal-noise situation (STR), the first output of which is the input of the transceiver antenna, and the second output is the input of the on-board micro-computer control device, connected by its output to the first input of the CAF SPO submodule.

The CAF SPO submodule includes two modules: an analog module based on the DAC3283EVM board manufactured by Texas Instruments USA / 7. Texas Instruments User Guide: USA, 2010 /, including a vector modulator, a clock generator, filter circuits, which allows it to be used as an analog signal generator, and a digital module based on the DE1-SoC Terasic Technologies USA / 8 debug board. User Guide for the DE1-SoC board Terasic Technologies: USA, 2014 / the configuration of which allows you to use it to implement the logic of the vector signal generator. This submodule provides digital-to-analog processing of generated signals and interference, as well as signals for controlling their radiation in relation to time. The CAF SPO submodule based on two circuit boards has mass-dimensional characteristics significantly lower compared to the SGT 100A / 9 type vector signal generator. SGT 100A User Guide. Germany: catalog of the company Rohde & Schwarz, 2015 /, used in the prototype 12. Complex formation of the signal-noise situation. - Patent for the invention RU No. 2626384, H04K3, 07/26/2017 / for the formation of a signal-noise situation.

A device is proposed that contains the essential features of the prototype: a receiving antenna connected in series with a receiving-excitation unit, which are located in the ground part of the device, as well as containing a UAV, which is the on-board part of the device, on which: the on-board micro-computer control device, and the onboard flight controller and the onboard UAV control device are interconnected, while the ground part of the device contains a ground control computer, the first output of which is the second the second input of the ground-based control computer is the input of the micro-computer control unit located in the ground part of the micro-computer control unit, connected via the radio channel to the on-board micro-computer control unit, the third output of the ground-based control computer is the input of the located in the ground part of the UAV control device, connected by radio with the onboard UAV control device, and the output with the third input of the ground control computer.

Comparative analysis with the prototype shows that the proposed device has other significant distinctive features of the prototype:

the presence of new elements - introduced: the tested radio electronic equipment, as well as those located on the UAV: a transceiver antenna connected via a radio channel to the receiving antenna and the tested radio electronic equipment, the output of which is the input of the receiver connected in series with the demodulator, the output of which is the second input of the CAF STR submodule, the first the output of which is the input of the transceiver antenna, and the second output is the input of the on-board micro-computer control device, connected by its output to the first input of the CAF STR submodule.

Below the invention and the essence of the proposed device are described in more detail.

In FIG. 1 shows a diagram of the proposed complex formation of the signal-jamming environment. This complex contains: a transceiver antenna - 1, a receiver - 2, a demodulator - 3, an on-board micro-computer control device - 4, a ground-based micro-computer control device - 5, an on-board flight controller - 6, an on-board control device for a UAV - 7, a ground device UAV control system - 8, receiving antenna - 9, receiving and exciting unit - 10, ground control computer - 11, unmanned aerial vehicle - 12, submodule CAF SPO - 13, tested RES - 14.

At the same time, airborne equipment is located on the UAV - 12: a transceiver antenna - 1, connected via a radio channel with a receiving antenna - 9 and the tested RES - 14, the output of which is the input of the receiver - 2 in series with the demodulator - 3, the output of which is the second input of the CAF submodule SPO - 13, the first output of which is the input of the transceiver antenna, and the second output is the input of the onboard micro-computer control device - 4, connected by its output to the first input of the CAF submodule SPO - 13, and also the onboard flight controller - 6, is connected th its output to the input of airborne drone control device - 7, the output of which is its input.

In addition, the ground part of the complex contains a series-connected receiving antenna - 9 and a receiving-excitation block - 10, the output of which is the first input of the ground control computer - 11, connected by its first output to its second input, and the second output to the input of the ground control device micro-computer - 5, connected by radio with the on-board control device of micro-computer - 4, and the output with the second input of the ground control computer - 11, the third output of which is the input of the ground control device UAV - 8, connected by rad okanalu skid control device UAV - 7, and output to the third input ground control computer - 11.

In this case, the receiving antenna - 9, is located in close proximity to the phase center of the tested RES - 14.

To implement the proposed technical solution, standard equipment can be used. So, for example, as: a transceiver antenna - 1, a log-periodic antenna of the AARONIA 9803/5 / 4 type can be used. User manual AARONIA 9803/5. Germany, 2016 /; receiver - 2 can be used receiver / 5. Radio receivers Under. ed. Zhukovsky A.P. - M.: Higher School, 1989, pp. 8-10 /; demodulator - 3 can be used demodulator / 6. Plashkov V.V. Radio receivers - M: Radio and communications, 1984, pp. 12-14 /; On-board micro-computer control device - 4 can be used radio type Radio Telemetry / 10. The manual for the radio modem. USA: catalog of the company Pixhawk, 2014 /; Micro-computer ground control device - 5 can be used radio type Radio Telemetry / 10. The manual for the radio modem. USA: catalog of the company Pixhawk, 2014 /; On-board flight controller - 6 An on-board flight controller such as Pixhawk / 11 can be used. Free encyclopedia of multicopter. USA: catalog of the company Pixhawk, 2016 /; UAV control unit UAV - 7 can be used with a radio modem like Radio Telemetry / 10. The manual for the radio modem. USA: catalog of the company Pixhawk, 2014 /; UAV ground control device - 8 can be used radio type Radio Telemetry / 10. The manual for the radio modem. USA: catalog of the company Pixhawk, 2014 /; receiving antenna - 9, an antenna of type P6-23A / 12 can be used. Operation manual for measuring antenna P6-23A. Belarus, 1995 /; receiver-excitation unit - 10, an Agilent E4407B / 13 type spectrum analyzer can be used. Agilent Test and Measurement Solutions. USA: Agilent catalog, 2008 /; ground control computer - 11 can be used ground control computer type personal computer based on the Intel / 14 processor. Intel processor catalog. USA, 2016 /; unmanned aerial vehicle - 12 can be used unmanned aerial vehicle type / 15. Unmanned aerial vehicle. - Patent for invention RU No. 2666493, B64C 39/00, 09/07/2018 /; CAF SPO - 13 submodule based on two boards; an analog module based on the DAC3283EVM / 7 board can be used. Texas Instruments User Guide: USA, 2010 /, digital module based on DE1-SoC / 8 board. User Guide for DE1-SoC board Terasic Technologies: USA, 2014 / and the test RES-14, a P-18R / 3 type radar can be used. Military technical training. Radar device RTV Air Force. Radar station P-18R: textbook .: at 2 hours. Part 1 / E.N. Garin, D.D. Dmitriev, V.N. Tyapkin et al .; ed. E.N. Garin. - Krasnoyarsk: Sib. Feder. University, 2012 y.

The proposed device operates as follows.

Before the functioning of the proposed complex for the formation of a signal-noise situation, the required (specified) signal and noise composition, as well as tactical signal-noise scenarios with a time reference are recorded in the memory of the CAF SPO - 13 submodule, as well as the required parameters of the signal and noise emission control signals with reference to time are recorded in the memory of the CAF SPO - 13 submodule. In addition, the required flight path of the UAV - 12 (flight plan) with time reference is recorded in the memory of the on-board flight control Dr. UAV - 6. Also, to synchronize the start of the test operation of RES - 14 and submodule TSAF ACT - 13.

To start the functioning of the proposed complex of the formation of the signal-noise situation on the ground control computer - 11, a control program is launched. UAV - 12 with reference to time carries out a flight on 6 points programmed in its flight controller. Flight information, including the coordinates and condition of the UAV equipment from the flight controller - 6 connected with its output to the input, and the input to the output of the onboard UAV - 7 control device is transmitted via its radio channel to the ground control unit UAV - 8, connected to the output with the third ground input Control computer - 11 for control and operational control of UAV flight by the operator. The CAF SPO - 13 submodule, through its first output, forms the required (specified) signal-noise situation, synchronized in time with the beginning of the operation of the tested RES - 14.

In the process of functioning of the tested RES - 14, radio signals from the output of its radiating antenna are received by a transceiver antenna - 1, connected via a radio channel to this RES, through the output of a transceiver antenna - 1, which is the receiver input - 2 signals are transmitted to a demodulator connected in series - 3 the output of which is the second input of the CAF SPO submodule 13. Based on the results of the demodulator - 3, the current radiation parameters of the tested RES - 14 are determined (carrier frequency, duration and pulse repetition rate, in id and parameters of intrapulse modulation, etc.), which are transferred to the CAF SPO - 13 submodule in real time to change the algorithm for generating signals and noise during testing.

The generated signal-noise situation from the output of the CAF SPO - 13 submodule is fed to the input of the transmitting and receiving antenna - 1, which emits signals and noise in the direction of the tested RES - 14 and the receiving antenna - 9, located in close proximity to the phase center of the tested RES - 14 Information about the created signal-noise situation through the on-board micro-computer control device - 4, connected by its output to the first input of the CAF SPO - 13 submodule, the second output of which is its input, is transmitted via radio to the ground th micro-computer control unit - 5, which by its output is connected to the second input ground control computer - 11 for monitoring and control signal formed by interference-operator environment. The receiving antenna - 9, receives signals and interference emitted by the transceiver antenna - 1, and transmits them to the first input of the excitation-excitation unit - 10, which is a signal analyzer that transmits them to the first input of the ground control computer via its output interface - 11 for operational monitoring and documentation. The control operator, observing on the monitor of the ground control computer - 11 the results of objective control by the tests: formed by the CAF SPO - 13 submodule and transmitted via the transmitting and receiving antenna - 1 via the radio channel to the receiving antenna - 9 and the receiving and exciting unit - 10 signal-jamming situation , the coordinates of the UAV position - 12 and the operating modes of the receiving-excitation unit - 10, if necessary, using the control program, promptly makes changes to the test plan through the ground control computer - 11, connected through the first output with the second input of the excitation-excitation unit - 10, through the second output with the input of the ground control device of the microcomputer - 5 and through the third output with the input of the ground control device of the UAV - 8, which are connected via the radio control channels to the micro - a computer - 4 and an onboard control device for a UAV - 7, respectively.

Thus, the use of the proposed complex will allow you to create the required (specified) signal-jamming environment for the RES by a mobile source of signals (interference) from various points in space with reference to the coordinates and time of operation of the tested RES and the source of signals (interference); generate time-consuming (several) tactical signal-jamming scenarios for one UAV flight due to a decrease in the mass-dimensional characteristics of on-board equipment; operatively and hardware-software control the generated signal-jamming situation, as well as conduct operational objective documentation of signal parameters, noise and the coordinate position of the signal source (noise).

This will improve the quality and efficiency of the justification of the parameters of the RES to assess their electromagnetic compatibility and noise immunity.

Distinctive features of the claimed complex formation of a signal-noise environment provide the emergence of new properties not achieved in the prototype and analogues. A comparative analysis of the known technical solutions (analogues) and the prior art in the studied and related subject areas made it possible to establish: there are no analogues with a set of features identical to all the features of the claimed technical solution, which indicates the conformity of the claimed invention to the “novelty” condition.

The search results for known solutions in the field of radar, radio engineering and antenna measurements in order to identify features that match the distinctive features of the prototype of the claimed complex showed that they do not follow explicitly from the prior art. Also, the popularity of the influence of the actions provided for by the essential features of the claimed invention on the achievement of the specified technical result was not revealed. Therefore, the claimed invention meets the condition of patentability "inventive step".

The invention is “industrially acceptable”, since the combination of characteristics characterizing it provides the possibility of its implementation, operability and reproducibility for the formation of the required (given) signal-jamming environment in the interest of assessing the quality of the functioning of RES, since standard industrial equipment can be used to implement the claimed complex and the present invention can be implemented in existing systems and complexes for evaluating noise immunity, electro gnitnoy compatibility and Information RES opportunities, and also used in various fields of radar, radio and measurement.

Claims (1)

Signal-jamming complex containing a receiving antenna connected in series with a receiving-excitation unit, which are located in the ground part of the device, and also containing an unmanned aerial vehicle (UAV), which is the airborne part of the device, which contains: the on-board micro-computer control device as well as an onboard flight controller and an onboard UAV control device, interconnected with each other, while the ground part of the device contains a ground control computer, the first output of which is is the second input of the excitatory unit associated with the output with its first input, the second output of the ground control computer is the input of the micro-computer control unit located in the ground part connected via the radio channel to the on-board micro-computer control device, the third output of the ground control computer is the input located in the ground part of the UAV control device, connected by radio with the onboard UAV control device, and the output with the third input of the ground control computer, characterized in that but a test radio electronic facility (RES) was introduced, as well as a transceiver antenna located on the UAV, connected via a radio channel to a receiving antenna located in the immediate vicinity of the phase center of the tested RES, and the tested RES, the output of which is the input of the receiver in series with the demodulator, the output of which is the second input of the sub-module of the digital-to-analog signal-jamming environment (CAF STR), the first output of which is the input of the transceiver antenna, and the second the input stroke of the on-board micro-computer control device connected by its output to the first input of the CAF SPO submodule.

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