RU2206155C1 - Transceiver module - Google Patents

Abstract

FIELD: antennas. SUBSTANCE: first radiator of transceiver module is connected to first side of first Y-junction circulator whose second side is connected to input of transmitting channel incorporating series-connected first controllable phase shifter, controllable attenuator, first gate, and power amplifier whose second input is connected to controllable pulse modulator. Connected to power amplifier output is first side of second Y-junction circulator whose second side is coupled with second radiator and third one, with first side of third Y-junction circulator; connected to third side of the latter is matched load and to second one, receiving channel input. It has series- connected protective gear, low-noise amplifier, second gate, and second controllable phase shifter whose output is connected to third side of first Y-junction circulator. Control inputs of first and second controllable phase shifters, attenuator, and controllable pulse modulator are coupled with respective outputs of control microprocessor unit. EFFECT: simplified design and enhanced reliability of transceiver module. 1 cl, 1 dwg

Description

 The invention relates to radio engineering, in particular to the transmitting and receiving elements of antennas, and can be used in large pass-through active phased array antennas (AFAR) of the microwave range with electric beam scanning.

 A known transmitting and receiving module (PPM) for AFAR, comprising a first "transmit-receive" switch, the first contact of which is connected to the output terminal of the transmitter of the radar station, and the second contact is to the input of the controlled phase shifter, to the output of which a controlled attenuator is connected in series and a buffer amplifier, the output of which is connected to the first contact of the second transfer-receive switch, to the second contact of which a pre-amplifier and a power amplifier are connected in series and, the output of which is connected to the first arm of the circulator, the second arm of which is connected to the PPM emitter, and the third arm to the first contact of the third transfer-receive switch, the second contact of which is connected to the matched load, and the third contact to the input of the low-noise amplifier, the output of which is connected to the third contact of the first transfer-receive switch. The third contact of the second transmit-receive switch is connected to the input terminal of the radar receiver. In addition, the PPM is equipped with a phase and amplitude error correction system, which is connected to a controlled phase shifter and a controlled attenuator. Thus, in this device, a controlled phase shifter, a controlled attenuator and a buffer amplifier are common elements of the transmitting and receiving channels of the PPM [1].

 A disadvantage of the known PPM is the impossibility of its use in passing AFAR, because it is powered directly from the radar transmitter. In addition, a large number of switches requires very high accuracy of synchronization of their work, constant correction of phase and amplitude errors, which complicates the design and, accordingly, reduces the reliability of the device.

 This drawback is partially eliminated in the MRP containing an antenna switch, one arm of which is connected to the transmitter, the second to the radar receiver, and the third to the sequentially connected controlled attenuator, controlled by the phase shifter and the first arm of the microwave switch, the input of the transmitting channel is connected to the second arm containing a pre-amplifier and a power amplifier connected in series, the output of which is connected to the first arm of the Y-circulator, the second arm of which is connected to the emitter, and the third arm - with the input of the receiving channel containing a series-connected protective device, a low-noise amplifier and a terminal amplifier, the output of which is connected to the third arm of the microwave switch. The controlled attenuator and phase shifter, the microwave switch are connected to the control microprocessor and are common elements for the transmitting and receiving channels of the PPM. All elements of the device are made according to planar technology and on integrated circuits [2, 3, see drawing].

 The reason that impedes the obtaining of the technical result indicated below when using the known PPM (prototype) is the fundamental need to switch (reconnect) the microwave inputs and outputs of the PPM and phase shifter from the receiving channel to the transmitting channel and vice versa, as well as phase shifting of the phase shifter when changing the reception / transmission modes, which limits radar performance and the class of probing signals used. In addition, the construction of a well-known PPM requires the availability of high-speed microwave switches (at least 3) with an appropriate wiring system for control commands and signals on the AFAR canvas with a high degree of time synchronization, which reduces the reliability of its operation.

 The invention consists in the following.

 The objective of the claimed invention is to simplify the design and increase the reliability of the transceiver module, suitable for work in the passage AFA lens type.

 The specified technical result is achieved by the fact that in the known receiving-transmitting module containing a controlled attenuator, a first controlled phase shifter, a power amplifier, a second Y-circulator, a second emitter, a protective device, a low-noise amplifier, a microprocessor control, according to the invention, a first pulse-controlled emitter is introduced modulator, first and third Y-circulators, first and second valves, matched load, while the first emitter is connected to the first arm of the first Y-circulator, to the second at the shoulder of which is connected the input of the transmitting channel, which contains in series the first controlled phase shifter, the controlled attenuator, the first valve and power amplifier, the second input of which is connected to a controlled pulse modulator, and the first shoulder of the second Y-circulator is connected to the output, the second shoulder of which is connected to the second a radiator, and the third - with the first arm of the third Y-circulator, to the third arm of which a matched load is connected, and to the second - the input of the receiving channel, which consistently includes a protective device, a low-noise amplifier, a second valve and a second controlled phase shifter, the output of which is connected to the third arm of the first Y-circulator, while the control inputs of the first and second controlled phase shifters, attenuator, and controlled pulse modulator are connected to the corresponding outputs of the control microprocessor.

Thanks to the claimed combination of new features of the invention (passive Y-circulators, passive protective device in the receiving channel, a modulator for valveing the low-frequency power amplifier, individual valves and controlled phase shifters in the transmitting and receiving channels) are achieved:
- the maximum simplification of the wiring system on the canvas AFAR microwave signal excitation PPM;
- significant facilitation of the work using quasicontinuous pulse-burst signals, because forced switching of the anti-theft pathway when changing the modes of "reception-transmission" is excluded;
- effective protection of the receiving channel both from the isolation signal during the emission of the probing signal, and from powerful external microwave influences;
- the possibility of independent control of the phase distribution in the AFAR aperture in the transmitting and receiving modes, which ensures the independent formation of the phase distribution in the AFAR aperture during reception and transmission, which significantly increases the radar's functionality and allows the most efficient use of microwave power of the AFM APM;
- elimination of noise of the transmitting channel in the pause between the emitted pulses.

 The invention is illustrated in the drawing, which shows a structural diagram of a transceiver module of an active phased antenna array.

 The transmit-receive module of the active phased antenna array contains a first emitter 1 connected to the first arm of the first Y-circulator (C-1) 2, the input of the transmitting channel is connected to the second arm of the receiver, and the PPM receiving channel is connected to the third arm. The PPM transmitting channel includes a series-connected first controlled phase shifter (Ф-1) 3, the input of which is a channel input, controlled attenuator (Att.) 4, the first valve (В-1) 5 and the power amplifier (УМ) 6, to the second the input of which is connected to a controlled pulse modulator (M) 7. The output of UM 6 is connected to the first arm of the second Y-circulator (C-2) 8, to the second arm of which a second emitter 9 is connected, and to the third arm, the first arm of the third Y-circulator ( C-3) 10. Its second shoulder is connected to the input of the PPM receiving channel, and the third letcho - a matched load 11, made for example in the form of a resistor having one end connected to the housing MRP. The receiving channel PPM includes a series-connected protective device (memory) 12, the input of which is the channel input, a low noise amplifier (LNA) 13, a second valve (B-2) 14 and a second controllable phase shifter (F-2) 15, the output of which is connected with the third shoulder of the first Y-circulator 2.

 The first 1 and second 9 emitters can be made in the form of printed vibrators on a dielectric substrate. The first 2, second 8 and third 10 Y-circulators are made in the form of passive printed Y-circulators. In this case, the first emitter 1 and the first C-1 2 provide isolation of the transmitting and receiving channels of the PPM from the AFAR irradiator, and the second C-2 8 and the second emitter 9 - decoupling of the transmitting and receiving channels from the outside. As F-1 3 and F-2 15 used four-digit discrete phase shifters with digital control. As att. 4 a four-digit discrete digital attenuator is used. Valves in the form of printed Y-circulators with absorbing load in one of the arms were used as B-15 and B-2 14. The valves are designed to prevent self-excitation of the transmitting and receiving channels of the PPM. As UM 6, a five-stage amplifier was used, in the low-frequency power circuit of which a controlled pulse modulator (M) 7 is included, made in the form of a transistor switch. The memory 12 is a passive high-speed protective device made in the form of microassemblies on microwave restrictive pin diodes. As LNA 13, a three-stage amplifier based on GaAs field-effect transistors with a Schottky barrier (PTSH) was used. Control inputs F-1 3, F-2 15, Att. 4 and M7 are connected to the corresponding outputs of the microprocessor (MP) 16, made, for example, on logical silicon-metal-oxide-semiconductor super-large integrated circuits (CMOS VLSI).

 The described AFM AFM is made according to planar technology and on integrated circuits. Structurally, it is mounted on dielectric plates, which are assembled in blocks and installed in the power housing AFAR.

 APM AFAR works as follows. The sounding microwave signal from the AFAR irradiator passes through the ether to the first emitter 1 and then, after passing the first arm of the first Y-circulator Ts-1 2, it enters the transmitting channel to the input of the first controlled phase shifter F-1 3. Due to the properties of the Y-circulator, this the signal does not enter the receive channel. In F-1 3 the signal acquires a phase shift in accordance with external digital control codes received at its control inputs from the microprocessor MP 16. Next, the signal is fed to the input of the attenuator Att. 4, in which its amplitude is regulated in accordance with external digital control codes supplied to its control inputs from MP 16. To prevent self-excitation of the PMD, the microwave signal from the output of Att. 4, the UM 6 power amplifier is fed to the input of the power amplifier through the first V-1 valve 5. In the UM 6, the microwave signal is linearly amplified and pulse modulated using the M 7 modulator, which valve the powerful low-frequency power supply of the amplifier in accordance with an external control signal supplied to the control the input M 7 is from MP 16. From the output of the UM 6, the generated microwave probe signal enters the first arm of the second Y-circulator C-2 8, leaves its second arm, enters the second emitter 9, and is radiated into the external space. The receiving channel at this moment operates in the locking mode, in which a parasitic microwave signal of increased power, reflected from the second emitter 9 and passed to the third arm of C-2 8 (or an external microwave signal from the outer space), falls into the first arm of the third Y -circulator C-3 10, leaves its second shoulder and is fed to the input of the protective device ZU 12, which at this moment jumps into the locking (restriction) mode. Reflected from the input of the memory device 12, the parasitic microwave signal returns to the second arm of the C-3 10, leaves its third arm and is extinguished in the matched load 11. Thus, on the one hand, the low-noise amplifier LNA 13 of the receiving channel is protected from unacceptably powerful parasitic microwave input signals, and on the other hand, the PA 6 of the transmitting channel is protected from the influence of the microwave signal reflected from the memory 12, which in the absence of the C-3 10 and the coordinated load 11 would get to the output of the PA 6.

 Reception of useful signals is carried out in pauses between pulses emitted by the PPM transmitting channel, and in the absence of powerful external interfering microwave influences at the input of the receiving channel. A useful microwave signal coming from external space is received by the second emitter 9, passes from it to the second arm of C-2 8, leaves its third arm, enters into the first arm of C-3 10 and, coming out of its second arm, enters the input of the protective storage devices 12. If the level of the received microwave signal does not exceed the threshold set in the storage 12, then it passes further to the input of the low-noise amplifier LNA 13, is linearly amplified, passes through the second gate В-2 14 and is fed to the input of the second controlled phase shifter Ф-2 15. Here the microwave signal acquires the shift in accordance with the external digital control codes received at its control inputs from the microprocessor MP 16. From the output of Ф-2 15, the microwave signal passes to the third arm of the first Y-circulator Ts-1 2, leaves its first arm, falls into the first emitter 1 is focused by it and through the ether it enters the receiving part of the AFAR irradiator.

Sources of information
1. US 5093667, 1992, Int. Cl. H 01 Q 3/26, US C1, 342/372.

 2. US 5745076, 1998, Int.Cl. H 01 Q 3/24, US C1, 342/372.

 3. US 5940031, 1999, Int.Cl. H 01 Q 3/26, US C1, 342/372.

Claims (1)

 The transmitter-receiver module of the active phased antenna array containing a controlled attenuator, a first controlled phase shifter, a power amplifier, a second Y-circulator, a second emitter, a protective device, a low-noise amplifier, a control microprocessor, characterized in that a first radiator, a controlled pulse modulator, is introduced into it , the first and third Y-circulators, the first and second valves, the coordinated load, while the first emitter is connected to the first arm of the first Y-circulator, to the second arm of which the input of the transmitting channel is connected, which includes the first controlled phase shifter, the controlled attenuator, the first valve and power amplifier, the second input of which is connected to a controlled pulse modulator, and the first shoulder of the second Y-circulator, the second shoulder of which is connected to the second emitter, is connected to the output the third - with the first arm of the third Y-circulator, to the third arm of which a matched load is connected, and to the second - the input of the receiving channel containing the protective device in series ystvo, low noise amplifier, a second valve and a second controlled phase shifter, the output of which is connected to the third port of the first Y-circulator, wherein the control inputs of the first and second controllable phase shifters and attenuators controlled pulse modulator associated with the respective microprocessor control outputs.