RU2694117C1 - Module for switching low-power microwave signals and a method of switching microwave signals in a decoupling device - Google Patents

Abstract

FIELD: antenna equipment.

SUBSTANCE: invention relates to microwave equipment and can be used in transceiving modules of active phased arrays (APAA) and other devices for switching of receiving-transmitting channels. In the proposed module for switching low-power microwave signals for transceiving equipment, switching (commutation) of the external microwave signal is performed from any input to any output of the module, to both outputs simultaneously or to a mode where all channels are switched off. Used circuit and structural solutions make it possible to create a module of high degree of integration, to minimize its weight and dimensions as much as possible, while maintaining high operational level of resistance to external influences and meeting requirements for electric parameters.

EFFECT: increased decoupling between channels, increased reliability, reduced dimensions.

2 cl, 2 dwg

Description

The invention relates to microwave technology and can be used in transceiver modules of active phased arrays (AFAR) and other devices for switching transmitting-receiving channels.

Known multichannel microwave strip switch (USSR author's certificate No. 1840040, 1984), in which each of the switching groups consists of two diodes and a quarter-wave segment of the line, connected in series in the microstrip line. This switch has a large size and a narrow frequency range, due to the use of half-wave line segments.

As a prototype of the selected diode switch two channels of the feeder path, containing a T-shaped branching transmission lines, the first arm of which is the input of the switch, and the other two shoulders - two switch outputs (USSR author's certificate No. 1437940, 1988). The main disadvantage of such a switch is not a sufficiently high level of microwave input power at low junction between the output channels. In order to ensure the operability of the switch with a higher power passing signal, an increase in the number of switched diodes is necessary, leading to a decrease in switch reliability and an increase in losses in the receiving channel.

The technical problem is the possibility of switching an external signal from any input to any output of the module.

The technical result of the claimed invention is to increase the isolation between the channels, increase reliability, reduce the size.

For this purpose, a low-power microwave signal switching module for receiving-transmitting equipment, made in hermetic design with coaxial microstrip junctions for coaxial microwave inputs and outputs, contains microwave inputs connected to the corresponding preliminary wideband amplifiers of the input microwave signals, the output of each of which is connected to the corresponding a power divider into two output channels, each of which is connected to a corresponding non-reflective channel selector, as well as an amplifier output A channel connected to the microwave output of a switching module, characterized in that each output channel includes a signal adder and an amplitude equalizer, each non-reflecting channel switch being made as a first and second switch, and the input of the first switch is connected to the corresponding output of the corresponding power divider two output channels, and its outputs are connected to the input of the second switch and the inputs of the first switch of the non-reflective switch of the channels of another input channel, outputs the second switches of the non-reflective switch of the first and second input channels through an adder connected to the input of the output channel amplifier, the output of which is connected to the amplitude equalizer to compensate for uneven transfer coefficient in the operating frequency range method of switching low-power microwave signals for receiving and transmitting equipment with two microwave inputs and two microwave outputs, including two amplifying switchable signals and dividing them by power into two switching channels operating independently and serving to turn on / off the microwave path along the signal path from the input to an arbitrary output of the module, while transmitting the signal from the first microwave input to the first microwave output of the single chip the switch moves the signal towards the first microwave output, and the second chip turns off the path towards the second microwave output; when transmitting signals from the first microwave input to the second microwave output, the second chip switches The main circuit shifts the path towards the second microwave output, and the first chip turns off the path towards the first microwave output, the chips of the other switch pair from the second input switch to unused outputs, while transmitting signals from the first microwave input to two microwave outputs simultaneously, one switch switches the path one microwave output, and another chip transfers the signal to another microwave output, after passing through the first switching channel path, the signal goes to the second switching stage to increase the 60-70 dB per power divider to sum the signal, wideband amplification and amplitude correction of the microwave signal, providing the required uneven transmission coefficient in the operating frequency range by introducing additional active losses at low frequencies of the operating frequency range; and one input of the switch, the second input is loaded, to the unused input of the second switch chip from the pair of switches.

FIG. 1 shows a block diagram of a low power microwave signal switching module.

FIG. 2 shows the appearance of the module (without the pressure cap).

The block diagram (Fig. 1) of the low-power microwave signal switching module contains:

Microwave inputs 1, 2, pre-wideband amplifiers 3, 4, power dividers 5, 6 into two output channels 7, 8, non-reflecting switches of channels 9, 10, 11, 12, 19, 20, 21, 22 in output channels 7, 8 , adders 13, 14 amplifiers 15, 16, amplitude correctors 17, 18 to compensate for uneven transmission coefficient in the operating frequency range, the outputs of amplitude correctors through power amplifiers 23, 24 are connected to the corresponding microwave output of the switching module.

Microwave switches are actively used for amplitude manipulations of high-frequency oscillations in modern paths of transceiver systems.

In the majority of microwave switches for AFAR, p-i-n-diodes and field-effect transistors are used as active elements, which allow, in comparison with circulators, to ensure a gain in size, mass and cost. The most common and effective, in terms of stable performance of microwave switches, are diode switches.

At the same time, in connection with the increase in the microwave power level of the transmitters, the requirements for the reliability of microwave devices designed to protect the input paths of the receivers increase.

In the proposed module, the external microwave signal is switched (switched) from any input to any output of the module, to both outputs simultaneously or to the mode in which all channels are turned off.

Switching signals in the frequency range from 0.1 GHz to 40 GHz is necessary, for example, when switching the antenna between several transmitters and / or receivers, for connecting redundant blocks, preselection filters or power dividers, using multi-element antenna systems and in other situations.

The operating frequency range of the module determines the choice of the basic technology, the types of inputs and outputs of energy, power and control signals, as well as transmission lines of electromagnetic energy.

The module is made in a sealed metal case with coaxial microwave outputs and inputs (coaxial microstrip junction), the characteristic impedance is 50 Ohms.

The module is generally grounded through the metal lobes directly onto the chassis ground.

The functioning of the module is as follows:

For correct operation, the input signal must be in the working frequency range from 2 GHz to 18 GHz and have a power level of no more than 1 mW.

Pre-amplification of the microwave signal to the input 1 (or input 2) is provided by amplifiers 3, 4, built using a broadband amplifier.

The division of power into two channels in the direction to the output 7 and the output 8 is carried out by a power divider (adder).

The power divider in dividers (adders) 5, 6, 13, 14 is a three-unit Wilkinson bridge with elements of an artificial line, made using microstrip technology, on a substrate made of polycor, and has super miniature dimensions of 18 × 10.25 mm. The divider provides power division into two channels with equal amplitude and phase. The transfer ratio of the divider from the summing input to one of the outputs is at least -5 dB. The spread of the transmission coefficient between channels ± 0.5 dB (with the same load of both channels). Isolation between channels of at least 10 dB.

Each output of the divider 5, 6, 13, 14 are connected in series by two switches 9, 12 and 10, 11.

The module contains two coaxial microwave inputs 1, 2 and two coaxial microwave outputs 7, 8.

The possibility of switching (switching) an external microwave signal from any input to any output of the module or to both outputs simultaneously is realized in the module. Also possible is the mode in which all channels are turned off. The electrical isolation between any on and off channels, in the working frequency range, is 65-70 dB.

Switching occurs as follows (left- and right- is determined in accordance with Fig. 1):

If you want to transmit a signal from input 1 (input 2) to output 7, then the left pair of switches turns on the path towards output 7, and the right pair of switches cuts off the path towards output 8. The microcircuits of the right pair of switches are switched to unused inputs.

If it is necessary to transmit a signal from input 1 (input 2) to output 8, then the right pair of switches turns on the path towards output 8, and the left pair of switches turns off the path towards output 7. The chips of the left pair of switches are switched to unused inputs.

If it is required to transmit a signal from input 1 (input 2) to output 7 and output 8 simultaneously, then the left pair of switches turns on the path towards output 7, and the right pair of switches turns on the path to exit 8.

If it is required to ensure the off state, the left pair of switches shuts down the path towards output 7, and the right pair of switches shuts down the path towards exit 8. Chips of the left and right pairs of switches are switched to unused inputs.

After passing through the channel switching path, the signal goes to one of the inputs of the adder (divider) 13, 14 of power.

To ensure the required values of the gain, two amplifying nodes, built using broadband amplifiers, are installed at each output of the module. An amplitude equalizer 17 is provided between amplifiers 15 and 24. An amplitude equalizer 18 is provided between amplifiers 16 and 23. Amplitude equalizers 17, 18 provide the required uneven gain in the operating frequency range by adding additional active losses at low frequencies in the operating frequency range. The correction level of the amplitude-frequency response is at least 8-10 dB at 2 GHz. Losses at 18 GHz do not exceed 2-3 dB. Proofreaders are made by microstrip technology, on a substrate made of polycore and include five correction units.

Switches 9-19, 10-20, 22-11, 21-12 work synchronously and serve to turn on (turn off) the microwave path along the signal path from input 1, 2 to the outputs of module 7, 8. Using a pair of switches provides isolation between channels and the desired value of the channel gain in the off state. The design and location of the internal partitions of the module, the distance between the switches in a pair (about 20 mm) was chosen taking into account the electrical tightness of the module, eliminating the influence of parasitic volume intra case radiation and feedback.

When the switch is turned on, only the output and one input of the switches 19, 20, 21, 22 are used in the path, the second input is loaded. The load of the unused non-reflective input of the switches 19, 20, 21, 22 is made by electrically connecting with the unused input of the nearest chip from a pair of switches of the adjacent channel of the module.

This method of loading ICs eliminates the need for additional broadband load resistors and, thus, significantly reduce the size and size of the module.

The inner space of the housing, the components and their fastening parts are designed in such a way as to maximally ensure the electrical tightness of the module and eliminate parasitic connections through the volume that occur between the nodes.

The used circuitry and design solutions make it possible to create a module of a high degree of integration, minimize its weight and dimensions as much as possible while maintaining a high operational level of resistance to external influences and meeting the requirements for electrical parameters.

Claims (2)

1. Module switching signals microwave low power for receiving and transmitting equipment, made in a sealed design with coaxial microstrip junctions for coaxial microwave inputs and outputs, containing microwave inputs connected to the corresponding pre-broadband amplifiers of the input microwave signals, the output of each of which is connected to the corresponding a power divider into two output channels, each of which is connected to a corresponding non-reflective channel switch, as well as an amplifier output channel connected to the microwave output of the switching module, characterized in that each output channel includes a signal adder and an amplitude equalizer, each non-reflective channel switch made in the form of a first and second switch, while the input of the first switch is connected to the corresponding output of the corresponding power divider output channels, and its outputs are connected to the input of the second switch and the inputs of the first switch of the non-reflective switch of the channels of another input channel, the outputs of the second switch The switches of the non-reflective switch of the first and second input channels through an adder are connected to the input of the output channel amplifier, the output of which is connected to the amplitude equalizer to compensate for uneven transmission coefficient in the operating frequency range, the output of the amplitude corrector is connected to the corresponding microwave output of the switching module. 2. Method of switching low-power microwave signals for receiving and transmitting equipment with two microwave inputs and two microwave outputs, including pre-amplification of switched signals and dividing them by power into two switching channels operating independently and serving to enable / disable the microwave path along the path signals from the input to an arbitrary output of the module, while transferring a signal from the first microwave input to the first microwave output of the chip of one switch converts the signal to the first microwave output, and the second chip MA disables the path towards the second microwave output, when transmitting signals from the first microwave input to the second microwave output, the second switch chip switches the path to the second microwave output, and the first chip disables the path towards the first microwave output, the other switch pair from the second input switches to unused outputs; when transmitting signals from the first microwave input to two microwave outputs, one switch chip simultaneously transfers the path to one microwave output, and the other chip transfers the signal to the other after the passage through the first switching path of the channels, the signal goes to the second switching stage to increase the isolation by 60-70 dB to the power divider to sum the signal, wideband amplification and amplitude correction of the microwave signal, providing the required uneven transmission coefficient in the operating frequency range by making at low frequencies of the working range additional active losses, when turning on the switch chip in the path, only the output and one input of the switch are used, second th input is loaded on an unused input of the second switch circuit pair of the switches.

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