RU121673U1 - Microwave Balance Amplifier - Google Patents

Abstract

A balanced microwave amplifier containing two amplifiers identical in parameters connected between the cascaded input and output three-decible directional couplers, characterized in that the ballast circuit of the input three-decibel directional coupler contains a calibration signal input unit, and each output arm of the output three-decibel directional coupler through a controlled switch can be connected either to the output of a balanced microwave amplifier, or to a matched ballast load, while amplifiers of identical parameters at their inputs contain reflective-type power limiters.

Description

The proposed technical solution relates to radio engineering and can be used as a receiving amplifier for active phased antenna arrays (AFAR) with an integrated testing and calibration system where high sensitivity values are required.

As you know, the sensitivity of the receiver is mainly determined by the direct signal loss on the way from the antenna to the input of the low-noise amplifier (LNA) of the receiving amplifier and the LNA's own noise.

At present, AFAR with digital beamforming and with a built-in system for testing and calibration of analog receiving amplifiers are widely used, in the input path of which a switching circuit of the input signal source is introduced, [V.Yu. Kochetkov. “The structure of channel paths of digital antenna arrays”, University News. ELECTRONICS No. 5 (79) 2009, p.68]. In this case, the losses introduced by the switch lead to a decrease in the sensitivity of the receiver.

The method of inputting a calibration (test) signal into the receiving amplifiers by means of a directional coupler is also quite widely known [A.V. Kondratenko, A.I. Miller, E.N. Sungatullin, M.L. Shevlyakov, “Twenty-four-channel frequency-separation device” , Microwave engineering and instruments, 2008, No. 2 p.6]. Since the test signal is powerful enough, the coupling of the directional coupler to the input is weak, with virtually no loss. Therefore, receiver sensitivity does not decrease. However, since the input of the receiver from the antenna is not disconnected, in the conditions of interference testing is difficult, and calibration is hardly possible.

In practice, there are intermediate options. For example, a calibration signal is fed to the input of the LNA of the receiving amplifier through a directional coupler, and the antenna, at the same time, is turned off by the input key, which is a protection element (power limiter), the presence of which is still necessary in the receiving amplifier. In this case, the disadvantage is that the path from the antenna to the LNA input is not subjected to testing and calibration, and this despite the fact that the input protection node (power limiter) is the most unreliable element of the receiving amplifier.

The greatest application as an input receiving microwave amplifier was found by a balanced amplifier [L.G. Maloratsky Microminiaturization of microwave elements and devices. Moscow “Soviet Radio” 1976. p.197, 198.], which is the closest analogue (prototype) of the claimed technical solution. The balanced amplifier contains two identical in parameters amplifiers, which are connected between the cascade-connected input and output three-decibel directional couplers. The signal received at the input arm of the input three-decibel directional coupler is divided into equal parts by power, and the signals at the outputs of the three-decibel directional coupler acquire a 90 degree shift relative to each other. Next, the signals are fed to the inputs of amplifiers identical in parameters. In this case, the reflected wave from the mismatched (in connection with the minimum noise setting) inputs of the amplifiers passes the input three-decibel directional coupler in the opposite direction, and due to the acquisition of an additional 90 degree phase shift in one of the arms, it is released at the matched ballast load, thereby ensuring good coordination at the input of a balanced amplifier. (These considerations are also true for the output of a balanced amplifier). Further, the amplified signals from the outputs of amplifiers identical in parameters are fed to the output three-decibel directional coupler and (due to the existing phase shift) are summed in one of its output arms, which go to the output of the balanced amplifier, and are subtracted in the other output arms, which go to the matched ballast load. The disadvantages of a balanced amplifier include its hardware redundancy. In fact, a balanced amplifier consists of two independent identical amplification channels, one of which amplifies the useful signal, and the other, in fact, amplifies the noise of the matched ballast load of the input three-decibel directional coupler. (The amplified noise and a part of the intrinsic noise of the amplifiers are allocated at the matched ballast load of the output three-decibel directional coupler).

The objective of the developed technical solution is to expand the functionality of a balanced microwave amplifier, by limiting the input signal power and switching the input signal to a calibration signal, without affecting the sensitivity of the input signal.

This object is achieved in that the balanced microwave amplifier contains two identical in parameters amplifiers connected between the cascade-connected input and output three-decibel directional couplers, moreover, the ballast circuit of the input three-decibel directional coupler contains a calibration signal input node, and each output arm of the three-decibel directional coupler output through a controlled switch can be connected either to the output of a balanced microwave amplifier, or to a matched ba lastnoy load, with identical parameters of amplifiers at their inputs include power limiters reflective type.

The utility model is illustrated by drawings.

The figure 1 shows an electrical schematic diagram of a balanced microwave amplifier.

The figure 2 shows a circuit diagram of a practical implementation of a balanced microwave amplifier with a directional coupler, as the input node of the calibration signal.

The figure 3 shows a circuit diagram of a practical implementation of a balanced microwave amplifier with an attenuator, as the input node of the calibration signal.

The microwave balanced amplifier contains two amplifier parameters 1 and 2, identical in parameters, connected between the cascade-connected input and output three-decibel directional couplers 3 and 4, respectively. The ballast circuit of the input directional coupler 3 contains a calibration signal input unit 5 and a matched ballast load 6, and each output arm of the output directional coupler 4 can be connected either to the output of a balanced microwave amplifier or to a matched ballast load 7 via a controlled switch 8. Identical in parameters amplifiers 1 and 2 at their inputs contain reflective power limiters of type 9 and 10.

The balanced microwave amplifier operates as follows. In the reception mode, the signal received at the input arm of the three-decibel directional coupler 3 is divided into equal parts by power, and the signals at the outputs of the three-decibel directional coupler 3 acquire a 90 degree shift relative to each other. Then, through the power limiters of the reflective type 9 and 10, the signals are fed to the inputs of amplifiers 1 and 2 identical in parameters. Moreover, due to a mismatch in the inputs of amplifiers 1 and 2 (usually associated with tuning to a minimum of noise), or the operation of reflective input limiters power 9 and 10 (with a high level of input power), the reflected wave from the inputs of amplifiers 1 and 2 passes a three-decibel directional coupler 3 in the opposite direction, and due to the acquisition of an additional 90 degree phase shift in one of leche, released in a coordinated ballast load 6, thereby providing good matching of the microwave input of the balanced amplifier. Further, the amplified signals from the outputs of amplifiers 1 and 2, identical in parameters, are fed to the output three-decibel directional coupler 4, where, thanks to the existing phase shift, they are summed in one of the output arms “output” and subtracted in the other output arm “ballast”. Moreover, in the reception mode, the controlled switch 8 connects the “output” arm of the output three-decibel directional coupler 4 to the output of the balanced microwave amplifier, and the “ballast” arm to the matched ballast load 7. Therefore, the amplified signal passes to the output of the balanced microwave amplifier, and the amplified ballast noise the load of the input three-decibel directional coupler 3 and part of the intrinsic noise of the amplifiers 1 and 2 is allocated to the agreed ballast load 7. In the calibration or testing mode, the controlled switch Chaser 8, by an external command, connects the “ballast” arm of the output three-decibel directional coupler 4 to the output of the balanced microwave amplifier, and the “output” arm, on the contrary, to the matched ballast load 7. Since, in the test and calibration mode, the input of the balanced microwave amplifier remains connected to the signal source, the input signal is amplified, just like in the reception mode, with the only difference being that the amplified input signal does not reach the output of the balanced microwave amplifier, but is allocated on a matched ba last load 7. The calibration signal supplied through the input unit 5 to the ballast arm of the first three-decibel directional coupler 3, due to the identity of the amplifiers 1 and 2 and the symmetry of the arms of the three-decibel directional couplers 3 and 4, is amplified in the same way as the input signal, but is summed in " ballast ”arm of the output three-decibel directional coupler 4 and then through the switch 8 is fed to the output of the balanced microwave amplifier, where it continues to participate in further testing and calibration of analog th part of the receiving tract. Since the balanced microwave amplifier does not have an input source switch, there are no losses associated with it. For subsequent stages of the receiving path, the role of the input source switch is played by switch 8, which does not affect the sensitivity of the receiver, and power limiters 9 and 10 are definitely tested during calibration, as they are part of a balanced amplifier.

(It should be noted that the calibration signal is fed through the cable in the reception cycle of the AFAR operation. In the transmission cycle, due to the mutual influence of the emitters, part of the transmitted power is returned to the receivers, where, reflected from the closed power limiters, it is mainly allocated to ballast resistors, and part of this power, through the input node of the calibration signal, penetrates the cable of the calibration signal, and in principle can be used, for example, for operational correction of the transmitting radiation pattern, since it carries information about the module and phase of the signal reflected from the antennas in the transmission cycle).

The proposed technical solution involves the diversity of its implementation, depending on the options for constructing the input node of the calibration signal. Two versions of the balanced amplifier of the microwave range 430 MHz were tested. In the first embodiment, a weak coupled directional coupler was used as the calibration signal input node (Fig. 2), and in the second embodiment, an attenuator was used (Fig. 3). The first option is oriented to work with a high level of input power, when the reflected power is transferred to a powerful ballast load located outside the receiving amplifier. The second option is more compact, but it is focused on working with lower input capacities.

Both options for the practical implementation of the balanced microwave amplifier circuit showed that while maintaining the parameters inherent in the prototype, this circuit has additional functionality that limits the input signal power and switches the input signal to a calibration signal without compromising the sensitivity of the input signal, while suppressing the input signal leaking to the output of a balanced microwave amplifier in testing and calibration mode, at least 20 dB.

Thus, the use of a balanced microwave amplifier of the developed design in the AFAR with an integrated testing and calibration system allows to increase the sensitivity of the AFAR.

Claims (1)

A microwave balanced amplifier containing two amplifiers identical in parameters, connected between cascade-connected input and output three-decibel directional couplers, characterized in that the ballast circuit of the input three-decibel directional coupler contains a calibration signal input unit, and each output arm of the three-decibel directional coupler output through a controlled switch can be connected either to the output of a balanced microwave amplifier, or to a matched ballast load, at Ohms, identical in parameters, at their inputs contain reflective power limiters.