BG1197U1 - Device for secondary radiolocation ground spotting - Google Patents

Abstract

The device for secondary radiolocation ground spotting is used when performing secondary radiolocation through active response, in the monitoring, spotting and control of moving objects with onboard radio-electronic responding equipment for land communication. The device is characterized by a high level of protection in the identification of moving objects through a friend-or-stranger question, as well as by a possibility for simplified modification or addition of functions and modes of operation through a FarmWare program and/or use of encryption. The device consists of an antenna module (1)mechanically coupled through a scanning implementation block (2) to a high-frequency pole (3), which is electrically interconnected with a junction board (4) connected in an output fashion to a receiver (5) and in an input fashion to the output of a transmitter (6), as well as by a control unit (7) interconnected respectively with the scanning implementation block (2), the junction board (4), the receiver (5), the transmitter (6), a digital screen (8), a control panel (9) and a communication unit (10). The control unit (7) consists of an encrypter (72), a decrypter (73), and a synchronization control module (71), whose output is connected through the encrypter (72) to the transmitter (6). The output of the receiver (5) is coupled to the decrypter (73), the outputs of the latter being connected respectively to the digital screen (8) and to the communication unit (10), whereat the synchronization control module is interconnected with the encrypter (72) and the decrypter (73). An additional power amplifier (11) is provided, whose input is connected to the output of the transmitter (6), while the output thereof is connected to the junction board (4).

Description

The utility model relates to a secondary ground-based radar detection device that is used to determine the presence of open air and naval objects, the identification of military and civilian aircraft, and of vessels in rapidly changing environments for accurate identification. high resolution and angular coordinates are required.

BACKGROUND OF THE INVENTION

A secondary ground-based radar detection device is known, consisting of a ground-based monitoring station for targets in a respective area in which an aircraft equipped with a transponder operating in S mode and a transponder operating in ATC modes (ZA + C) is located. The ground monitoring station consists of a transmission processor that controls the transmission of all S mode signals, including the ground station identification code, of a receiving processor that receives the responding signals and of a recognition processor. The recognition processor recognizes the response signal as well as the processing of the target when the identification information in the response signal received by the receiving processor coincides with the identification code of the ground station when the recognition processor recognizes the response signal as well as the signal processed by the target. also when the identification information contained in the response signal received by the receiving processor coincides with zero information / 1 /.

The secondary ground radar detection device has limited tactical capabilities with respect to the detection modes used, the lack of technical capabilities to use encrypted detection modes, to attach the image of the identified target to the coordinates of the area, to work with specialized codographic exchange systems information, as well as for pairing with different types of analogue or digital primary radar stations.

The technical nature of the utility model

The utility of the utility model is to provide a secondary ground-based radar detection device that has advanced tactical capabilities with respect to the detection modes used, such as the technical capabilities of using encrypted detection modes to attach the image of the target to the terrain coordinates , to work with specialized codographic systems for the exchange of information, as well as for coupling with different types of analog or digital primary radar stations.

In accordance with the utility model, this task is solved by means of a secondary ground-based radar detection device, consisting of an antenna module mechanically connected by a scanning unit to a high-frequency current collector, which is electrically interconnected with a switch output to a receiver and to the output of the transmitter from a control unit interconnected respectively to the scan execution unit, switch, receiver, transmitter, digital screen, control panel and communication unit. The control unit is composed of a cryptor, a decryptor and a control and synchronization module, the output of which is passed through the cryptor to the transmitter. The output of the receiver is connected to the handle, the outputs of which are fed to the digital screen and the communication block respectively. The management and synchronization module is interconnected with the cryptor and the descriptor. An additional power amplifier is provided whose input is connected to the output of the transmitter and the output is fed to the switch.

The advantages of the secondary ground-based radar detection device are that it has increased stability and stability with significantly improved noise protection; enables modification or addition of functions and modes of operation by using firmware and / or encryption; uses a minimum of hardware to achieve complete system control; has compact dimensions in dimensions with reduced energy consumption; provides flexible control capabilities through the use of a new generation of digital units and units, as well as a digital communications unit for connecting to users of secondary radar information, thereby aligning modes of operation when querying radar sites with existing international military standards; increased level of security when requesting "own / alien" of flying objects using signal encryption, which alters algorithms and keywords when asked on board aircraft; flexibility and introduction of more possibilities for further development of query modes by changing or refining the software of the control and encryption modules, which achieves the addition of changes in the modes of operation of the secondary radar, which are in line with the applied modern trends and inquiry methods; remote control, coupling and synchronization when starting and rotating with external radar stations; the information submitted is both analogue and digital; identification information is displayed at the built-in workstation in all recognition modes, ensuring that it is fed to other automated systems.

Explanation of the annexed figures

The utility model is explained in more detail by way of the exemplary embodiment of a secondary ground-based radar detection device shown in the figure by its block diagram.

Exemplary implementation of the utility model

As shown in the figure, the secondary terrestrial radar recognition device consists of an antenna module 1 mechanically connected by a scanning unit 2 to a high frequency current collector 3, by a switch 4 output to a receiver 5 input to the output of a transmitter 6 and interconnected electrically with the high-frequency recorder 3 and the control unit 7, from a digital screen 8 connected to the control unit 7, which is interconnected with the control panel 9 and with a communication unit 10, wherein the output of the transmission the atelier 6 is supplied by an additional power amplifier 11 to the switch 4.

The receiver 5 is constructed of a high-frequency digital converter 51 to which a reference frequency generator 52 and the output of the switch 4 are input, and the output of the high-frequency digital converter 51 is fed to an information processing unit 53.

The transmitter 6 contains a power amplifier 61, the output of which is fed to the input of the switch 4, a modulator 62 connected to its output to the power amplifier 61, a modulation control unit 63, interconnected and output connected to the modulator 62, and a generator of reference frequency 64, the output of which is fed to the modulator 62.

The control unit 7 is composed of a control and synchronization module 71 that is output connected to and interconnected with the cryptor 72, forming a common unit with the descriptor 73. The control and synchronization unit 71 is interconnected with the information processing unit 53, respectively. , the high frequency digital converter 51 and the reference frequency generator 52 of the receiver 5, with the switch 4, with the scanning unit 2, with the power amplifier 61, the reference frequency generator 64 and the modulation control unit 63 of the transmitter 6, with digital screen 8, the control panel 9 and the communication unit 10. The descriptor 73 is connected to the output of the information processing unit 53 of the receiver 5 and outputs respectively to the digital display 8 and to the communication unit 10.

All the equipment of the secondary radar described above, because of its compactness, allows it to be built together with an autonomous power supply unit not shown in the figure, in a common housing that can also be mounted on a movable platform, also not shown in the figure.

Application (use) of utility model

Using the control panel 9, in conjunction with the digital information screen 8, sets the modes of operation of the secondary radar as different ways of displaying the information on the digital screen itself 8, as well as the way of communication through the communication unit 10 with the users of the secondary radar information. After selecting the operating mode, the control and synchronization module 71 of the control unit Ί is activated, which generates the inquiry code and controls the cryptor 72 depending on the secondary radar operating mode selected. The cryptor 72 secures the requesting code and passes it directly to the modulation control unit 63 in the transmitter 6. Also, the control and synchronization module 71 sends control signals to the switch 4, which alternates the input of the antenna module 1 to the transmitter 6 or to the receiver 5 on the secondary radar. The control and synchronization module 71 monitors the status of the other modules from the secondary radar and controls the scanning of the antenna module 1 via the scanning execution unit 2, which can be designed as an electric motor with a gearbox, depending on the operation of the control panel 9. After transferring the request code to the cryptor 72, the control and synchronization module 71 switches on the cryptor 72 and the descriptor 73 in receiving mode or directly passing through them, depending on the operating mode selected from the control panel 9. 3 pitvashtiyat code kriptora 72 passes into the control unit 63. The modulation generator 64 generates reference frequency signal, for example with a selected frequency in MHz, which is modulated in the modulator 62 with a width of, for example selected bandwidth tens MHz. The modulated high-frequency signal from the modulator 62 is transmitted to the multistage high-frequency power amplifier 61, after which the amplified signal is transferred to the switch 4, which is timely switched to the output of the transmitter 6. The request code is transmitted via the high-frequency current picker 3 of the antenna module 1 as electromagnetic waves in space. Upon reaching the transmitted signal to the on-board equipment of the monitored aircraft, depending on the selected mode of inquiry, information on the transponder number - the aircraft identification number, various other flight characteristics, or a "own / foreign" request is returned to the secondary radar. The signal emitted by the aircraft enters the antenna module 1 and through the high-frequency current collector 3 and switch switch 4 falls at the input of the high-frequency digital receiver 51, where the signal is converted by digital sampling and filtered. The received frequency, for example MHz, is set as the reference frequency in the reference frequency generator 52 of the receiver 5 at an exemplarily selected sensitivity of 80 dB. After digitization and filtration of the received signal from the high-frequency digital converter 51, the signals enter the reference frequency generator 52, where the code combination of the response sent by the aircraft is processed and extracted. After processing in the reference frequent generator 52, the code of the "answer" falls into the descriptor 73, where it can be decrypted or recognized as "correct" and, accordingly, passed to the digital screen 8 for conversion into a convenient graphical representation, as well as to the communication block 10 for packing in an appropriate protocol for transmitting secondary radar information to different users. The condition for having the "right" answer is the pre-agreed one with respect to the same encryption algorithms and / or identical keywords, which are set equally in the aircraft and in the secondary radar.

By using the digital units and units in the proposed radar device for the secondary radar, as well as adding a digital communication unit 10 for digital communication with users of the secondary radar information, the modes of operation when requesting aircraft from the radar device with the accepted international ones are achieved. air standards. In addition, it is possible through the communication unit 10 to carry out remote control, control and operating modes of the secondary radar device.

The requesting signal to the aerial object is received at the input of the intended additional amplifier 11, then amplified several times and fed to the switching switch 4 and through the current collector 3 to the antenna module 1. The activation of the additional amplifier 11 is dictated by the distance range compliance requirement of familiarization with the primary radar area with which the proposed device is coupled while maintaining the predetermined detection probability.

In the exemplary embodiment of the device, the coupling is performed with longer-range radars detecting air and sea objects. As the predicted standard power of the amplifier 61 is not sufficient to cover the distance for reliable identification, it is necessary to include an additional amplifier 11.

The proposed device achieves a high degree of security when querying flying objects for "own / foreign" due to the use of encryption modules, which can programmatically change algorithms and keywords related to encryption of the signal on request, respectively in the onboard equipment of the flying aircraft monitored.

A significant advantage of the device is that it has the flexibility and more possibilities to further develop query modes by changing or refining the software in crypto modules, in which the modes of operation of the secondary radar can be added and changed in accordance with the latest trends and inquiry methods.

Claims (1)

1. A secondary ground-based radar recognition device, consisting of an antenna module, mechanically connected by a scanning unit to a high-frequency current collector, which is electrically interconnected with a switch output to a receiver and input to a transmitter output from a block for control interconnected respectively to the scan execution unit, switch, receiver, transmitter, digital screen, control panel and communication unit, characterized in that the control unit (7) is composed of a fertilizer (72), descriptor (73) and control and synchronization module (71), the output of which is fed through the cryptor (72) to the transmitter (6) and the output of the receiver (5) is connected to the descriptor (73), outputs to which are supplied respectively to the digital screen (8) and to the communication unit (10), with the control and synchronization module (71) interconnected with the cryptor (72) and the descriptor (73), providing an additional amplifier of power (11) whose input is connected to the output of the transmitter (6) and the output is fed to the switch (4).