RU197737U1 - SHF pulser with suppression of post-pulse radiation - Google Patents

Abstract

The utility model relates to the field of radar technology, in particular to devices for generating for transmitters of radar systems (radar) radio pulses of microwave frequencies (microwave) of nanosecond duration by the method of resonant microwave compression. The technical result of the development of this utility model is aimed at suppressing the end-to-end propagation of microwave energy from the microwave generator to the antenna system in the process of outputting the stored energy, as a result of which the radar characteristics are improved, namely, the near range of the radar is reduced. This result is achieved by the fact that in the shaper A microwave pulse containing a microwave generator, a coaxial storage resonator, a coupling element of a microwave compressor with a microwave generator, and a semiconductor switch, consisting of a toroidal cavity with PIN diodes located inside, transfer the coupling element from the coaxial cavity to the toroidal cavity of the semiconductor switch. 4 ill.

Description

The utility model relates to the field of radar technology, in particular to devices for generating ultra-high frequency (microwave) nanosecond radio pulses for transmitters of radar systems (radar) using resonant microwave compression and can be used to develop a nanosecond radar design.

One of the ways to create nanosecond microwave pulses for short-pulse radar systems is the method of resonant microwave compression (Didenko A.N., Yushkov Yu.G. Powerful microwave pulses of nanosecond duration. - M .: Energoatomizdat, 1984. - 112 p. ) The method of resonant microwave compression is based on the accumulation of microwave energy, which comes from the microwave generator to the storage resonator with its subsequent output in the form of a short pulse with an increased amplitude. The process of accumulation of microwave energy and its output to the load is provided by a switch connecting the storage resonator with the load, which is the radar antenna system. After the energy is removed from the storage resonator, the switch needs time to restore locking. During this time, the connection between the microwave generator and the antenna system is maintained, as a result of which at this time the microwave energy from the microwave generator enters the load. Compact radars using a single transmit-receive antenna during switch recovery cannot work in the mode of receiving radar pulses, as a result of which the near range of the radar increases. Thus, for radars using the method of resonant microwave compression, reducing the near field is one of the tasks that must be solved when designing these devices.

The objective of the claimed utility model is the suppression of post-pulse radiation during the recovery time of the switch.

, где

– фазовая постоянная. Фаза волны, отраженной от закорачивающей стенки бокового плеча тройника и поступающей в точку ветвления коаксиального соединения, изменяется и складывается в фазе с волной, поступающей из резонатора. Это означает, что накопленная в резонаторе энергия передается в выходное плечо тройника. При подключении выходного плеча тройника к согласованной нагрузке, накопленная энергия передается в нагрузку.Known pulse shaper (Patent SU No. 175219, published July 30, 1992) containing a microwave generator connected by a coupling element to a coaxial storage resonator, a coaxial tee, with a discharge gap in the side shoulder, and a coupling element of the shaper with a load in the output shoulder . Shaper works as follows. Electromagnetic energy from the microwave generator enters the internal volumes of the resonator and tee. In the process of accumulation, electromagnetic waves propagating in the lateral shoulder enter the outlet arm of the tee, add up in antiphase with waves propagating along the resonator, mutually cancel each other, and electromagnetic energy does not enter the load, accumulating in the resonator volume. At the end of the accumulation process, a microwave breakdown occurs in the lateral shoulder of the tee between the end surface of a segment of the inner conductor and the shorting wall. After that, the electric length of the side shoulder takes on the value

where

- phase constant. The phase of the wave reflected from the shorting wall of the lateral shoulder of the tee and entering the branch point of the coaxial connection changes and adds up in phase with the wave coming from the resonator. This means that the energy stored in the resonator is transferred to the output arm of the tee. When the output arm of the tee is connected to a matched load, the stored energy is transferred to the load.

The disadvantage of this device is the presence of post-pulse radiation, which propagates from the generator into the load after the output of the stored microwave energy.

Closest to the claimed device, the prototype is a microwave compressor of the shaper of microwave pulses of nanosecond duration, made on the basis of a PIN diode switch (Nikiforov A.A. Chumerin P.Yu., Slinko V.N., Vaulin V.A. Semiconductor L-band transmitter with compression of radiation pulses. Journal of Radio Electronics (electronic journal) 2018. No. 12. Access mode: http://jre.cplire.ru/jre/dec18/18/text.pdf)

The microwave pulse generator according to the prototype comprises (FIG. 1) a microwave generator 1, the output of which is equipped with a coaxial circulator 2. The direct output of the coaxial circulator 2 is connected to a communication loop 3 located in the storage part 4 of the coaxial resonator 5 of the microwave compressor 6, consisting from a coaxial resonator 5 and a semiconductor switch 7, which in turn includes a toroidal resonator 8 and PIN diodes located inside it 9. Coaxial resonator 5 consists of a storage part 4 and an output part 10. The outer conductor of the coaxial resonator 5 is broken by a semiconductor switch 7 consisting of a toroidal resonator 8 with PIN diodes inside. 9. The control device of the switch 11 is connected to a control electrode 12 connected via a connector in the housing of the toroidal resonator 8 to the PIN diodes 9. A load 13 is connected to the output part 10 of the coaxial resonator 5. Dimensions of the toroidal semiconductor resonator 8 the switch 7 is selected so that its resonant frequency, taking into account the capacitance of the PIN diodes 9, when a locking voltage is applied to them through the control electrode 12, coincides with the frequency of the microwave generator 1. Due to this condition for microwave currents, the resistance of the semiconductor switch 7 increases, and, consequently, the coefficient of transition attenuation of microwave energy in the mode of its accumulation in the storage part 4 of the coaxial resonator 5 is increased.

, где Z – входное сопротивление полупроводникового коммутатора,

– волновое сопротивление коаксиального резонатора, вследствие чего происходит накопление СВЧ-энергии в накопительной части коаксиального резонатора. При подаче прямого смещения на PIN-диоды 9 их сопротивление становится равным омическому сопротивлению внешнего проводника коаксиального резонатора, вследствие чего замыкается внешний проводник коаксиального резонатора и накопленная энергия поступает в нагрузку 13. Величина амплитуды послеимпульсного излучения для устройства по прототипу составляет 26 В (фиг.2.).The prototype device works as follows. Microwave energy from the microwave generator 1 enters the storage part 4 of the coaxial resonator 5 of the microwave compressor 6 through the communication loop 3. The control device of the switch 11 supplies the locking voltage to the PIN diodes 9. Through the total capacitance of the PIN diodes 9 and the toroidal resonator 8, playing the role of capacitive coupling of the semiconductor switch 8 with the coaxial resonator 5, part of the power of the microwave generator 1 enters the toroidal resonator 8. In this mode, the semiconductor switch 7 reflects the microwave energy supplied to its input with a reflection coefficient

where Z is the input impedance of the semiconductor switch,

- wave impedance of the coaxial resonator, resulting in the accumulation of microwave energy in the storage part of the coaxial resonator. When applying direct bias to the PIN diodes 9, their resistance becomes equal to the ohmic resistance of the external conductor of the coaxial resonator, as a result of which the external conductor of the coaxial resonator closes and the stored energy enters the load 13. The magnitude of the after-pulse radiation amplitude for the prototype device is 26 V (Fig. 2 .).

The disadvantage of the prototype is the significant amount of post-pulse radiation propagating from the microwave generator to the load after the output of the stored microwave energy.

The technical result of the claimed microwave compressor pulse generator is to reduce by more than an order of magnitude of post-pulse radiation.

The technical result is achieved by the fact that in the microwave compressor for generating microwave pulses with suppression of post-pulse radiation, including a communication loop, the microwave compressor is configured to connect a microwave generator, the output of which has a coaxial circulator, while the microwave compressor consists of a coaxial resonator and a semiconductor switch, which in turn includes a toroidal resonator and PIN diodes located inside it, configured to communicate with the switch control device through an electrode controlling PIN diodes, the toroidal resonator of the semiconductor switch is configured to be connected using loop connection, the output of the microwave generator through a coaxial circulator.

Due to the process of shorting the external conductor of the coaxial resonator and disruption of the connection of the microwave generator with the microwave compressor in the process of outputting the stored energy and during the recovery period of locking the switch, the transmission of microwave energy is reduced and the post-pulse radiation drops sharply.

The utility model is illustrated by the following figures.

Figure 1 Structural diagram of a prototype device.

Figure 2. The structural diagram of the inventive microwave compressor as part of a pulse shaper.

Figure 3 The waveform of the pulse generated by the prototype.

Figure 4 The waveform of the pulse formed with the inventive device.

The microwave pulse generator with suppression of post-pulse radiation based on the inventive microwave compressor contains a microwave generator 1, the output of which is equipped with a coaxial circulator 2. The direct output of the coaxial circulator 2 is connected to a communication loop 3 located in the toroidal resonator 8 of the microwave compressor 6, consisting from a coaxial resonator 5 and a semiconductor switch 7, which in turn includes a toroidal resonator 8 and PIN diodes located inside it 9. The coaxial resonator is formed by the storage part 4 of the coaxial resonator 5 and its output part 10. The outer conductor of the coaxial resonator 5 is broken by a semiconductor a switch 7, consisting of a toroidal resonator 8 with PIN diodes located inside 9. The control device of the switch 11 is connected to a control electrode 12 connected via a connector in the housing of the toroidal resonator 8 to the PIN diodes 9. A heating part is connected to the output part 10 of the coaxial resonator 5 narrow 13.

The SHF-pulse generator with suppression of post-pulse radiation operates as follows. The control device of the switch 11 supplies a locking voltage to the PIN diodes 9. The microwave energy from the microwave generator 1 enters the toroidal resonator 8 of the semiconductor switch 7 and through the capacitive coupling of the semiconductor switch 7 and the coaxial resonator 5 enters the storage part 4 of the coaxial resonator 5, due to why in it is the accumulation of microwave energy. When applying direct bias to the PIN diodes 9, the resistance of the diodes becomes equal to the ohmic resistance of the external conductor of the coaxial resonator, as a result of which the external conductor of the coaxial resonator 5 closes and the energy stored in the storage part 4 of the coaxial resonator 5 enters the load 13. During the output of the stored energy, capacitive coupling semiconductor switch 7 and coaxial resonator 5 is broken, because in this mode, the external conductor of the coaxial resonator 5 is closed by PIN diodes 9. Thus, the toroidal resonator 8 becomes a separate resonant system with a shifted resonant frequency relative to the frequency of the microwave generator 1, as a result of which the connection of the microwave generator 1 with the microwave compressor 6. the totality of these processes: shorting of the external conductor of the coaxial resonator and disruption of the connection of the microwave generator with the microwave compressor during the process of outputting the stored energy and during the recovery period of locking the switch, the transmission of microwave energy decreases and the post-pulse radiation drops sharply.

An example of practical implementation. A device was manufactured - a microwave pulse generator with suppression of post-pulse radiation for a nanosecond nonlinear radar, which contains a microwave generator from the NR-900EK3M KORSHUN nonlinear radar as a source of microwave radiation, the output of which is equipped with a coaxial circulator of the FTSK 3-37 brand IH. " The direct output of the coaxial circulator is connected to a communication loop made of copper with a cross section of 0.7 mm ² and located in a copper toroidal resonator of a microwave compressor, consisting of a copper coaxial resonator, the diameter of the outer and inner conductors of which is 32 mm and 12 mm, respectively, and a semiconductor switch, which in turn includes a toroidal resonator and 2A542A1 PIN diodes located inside it. The switch control device, consisting of an inverter and a control unit, is connected to a control electrode connected via PIN in the toroidal resonator housing to PIN diodes. A load in the form of an antenna system is connected to the output part of the coaxial resonator.

When you connect a microwave generator (according to the prototype), the amplitude of the after-pulse radiation for a device connected to a generator with a microwave compressor through a coaxial resonator was 26 V (Figure 3). When connecting the microwave generator to the inventive microwave compressor, the amplitude of the after-pulse radiation was 2 V (Figure 4.). Thus, it was shown that in the microwave pulse shaper using the inventive device there is a decrease in the value of post-pulse radiation by more than 10 times.

Claims (1)

A microwave compressor for generating microwave pulses with suppression of post-pulse radiation, including a communication loop, while the microwave compressor is configured to connect a microwave generator, the output of which has a coaxial circulator, while the microwave compressor consists of a coaxial resonator and a semiconductor switch, which in turn includes a toroidal resonator and PIN diodes located inside it, configured to communicate with a switch control device through an electrode controlling PIN diodes, characterized in that the toroidal resonator of the semiconductor switch is configured to connect, using a communication loop, an output Microwave generator through a coaxial circulator.

Images