RU2680859C1 - Microwave phase shifter on microstrip transmission lines of the dimeter wavelength range - Google Patents

Abstract

FIELD: radio equipment; electronics.SUBSTANCE: invention relates to radio engineering, in particular to phase shifters. Microwave phase shifter on microstrip transmission lines of the decimeter wavelength range contains two combined pin-diode discharge 11.25° and 5.625° on a loaded line, each with two pin diodes. Cathodes of the pin diodes are connected to two series-connected noise suppression filters, and the outputs of each discharge are combined and connected to the corresponding outputs of the control device and through the first capacitors connected to the housing. Anodes of the first two pin diodes discharges 11.25° and 5.625° are combined and are connected to the first input-output through the third capacitor, at the same time, the anodes of the second two pin diodes discharges 11.25° and 5.625° are joined and connected through a matching segment of a microstrip line, made in the form of a meander with a connection, with connected anodes of the first two pin diodes of discharges 11.25° and 5.625° and a grounded ninth noise suppression filter, connected through the fourth capacitor to the second input-output.EFFECT: reduction of phase setting errors.1 cl, 2 dwg

Description

The invention relates to the field of microwave electronics and can be used for discrete control of the phase of microwave signals, in particular, in phased antenna arrays with electronic beam control.

Transient microwave diode phase shifters on loaded lines are known, and pin diodes are included in the transmission line directly or through segments of transmission lines — loops (see, Radar Handbook, 1977, v. 2, edited by M. Skolnik, Moscow, Soviet Radio ; Pin - Dioden phasen schieber in symmetrischer Streitenleitungs technik, Brandle R. und Sedlmair S., "Frequenz", 26. 1972, No. 2, ss 45-50).

A disadvantage of the known technical solutions is not the adaptability of the phase adjustment.

Known microwave pass-through phase shifter on pin diodes (see, IEEE Transactions on Microwave Theory and Techniques, vol. MTT-13, 1965, No. 2, pp 233-242; JF White, High power, pin-diode controlled, microwave transmission phase shifters), containing a segment of the transmission line, to which one (input) ends are connected to the loops, the other ends of the loops are connected to pin diodes, the first electrodes of which are in contact with the current-carrying conductors of the loops, and the second electrodes are connected at high frequency through the passage capacitors to case, phase control is carried out by switching pin diodes, when switching and which the input reactive conductivity of the loops on which the segment of the transmission line is loaded is changed, therefore, the electric length of this line and, accordingly, the phase of the phase shifter gain change.

The magnitude and accuracy of setting the nominal phase values are determined by the magnitude and accuracy with which the corresponding values of the reactive components of the input conductivities of the loops are realized for two states of pin diodes.

The disadvantage of the technical solution is the lack of phase adjustment in it, which would allow smoothly regulating the input conductivity of the loops and thereby ensure that the nominal values of the controlled phase are set with the necessary accuracy. Therefore, the accuracy of setting the nominal phase values can be achieved only by careful selection of pin diodes according to the parameters and the corresponding manufacturing accuracy. This increases the requirements for pin diodes, complicates the manufacture and adjustment of the phase shifter.

The closest in technical essence is a two-bit microstrip phase shifter on a loaded line (see, IEEE Transactions on Microwave Theory and Techniques, vol. MTT-16, 1968, No. 7, pp 462-468; Francis L. OPP and WF Hofman, Design of digital loaded-line phase-shift networks for microwave thin-film applications, fig. 2, fig. 4), containing combined discharges of 11.25 ° and 22.5 °, each with two pin diodes, cathodes of pin discharge diodes 22.5 ° are connected to inductors connected to the control device and through capacitors to the housing; cathodes of pin diodes of the discharge 11.25 ° are connected to the control device through capacitors connected to housing, the anodes of all pin diodes are connected to the main transmission line, discharge 22.5 ° directly, and the discharge 11.25 ° through capacitors, the length of the main microstrip line between the connection points of the anodes of the first pin diodes of the discharges 11.25 ° and 22.5 ° and the second pin diodes of the discharges 11.25 ° and 22.5 ° is equal to λ / 4 (θ = 90 °) or 5λ / 24 (θ = 75 °), the connection point of the anodes of the first pin diodes of the discharges is 11.25 ° and 22.5 ° to the main line is connected to the first input-output, and the connection point of the anodes of the second pin diodes through an inductance and a capacitor connected to the housing, to the control device and W rum entry-exit, and to the anodes of the discharge pin-diodes 22,5 ° inductance connected in parallel, connected to the control through a capacitor connected to the housing.

The disadvantage of the technical solution is a narrow band of operating frequencies ± 2.5%.

The technical result of the invention is the creation of a small-sized broadband microstrip phase shifter of discharges of 5.625 ° and 11.25 ° with small errors in the installation of the phase.

The technical result is achieved by the fact that the microwave phase shifter on microstrip transmission lines of the decimeter wavelength range, containing two combined pin diode discharges 11.25 ° and 5.625 ° on the loaded line, each with two pin diodes, the cathodes of which are connected to two in series-connected noise suppression filters, the outputs of each discharge being combined and connected to the corresponding outputs of the control device and connected to the housing through the first capacitors, in addition, the anodes of the first two pin diodes of the discharges 11.25 ° and 5.625 ° r are connected and connected through the third capacitor to the first input-output, while the anodes of the second two pin diodes of discharges 11.25 ° and 5.625 ° are combined and connected through the matching segment of the microstrip line, made in the form of a meander with coupling, with the connected anodes of the first two pin -diodes of discharges 11.25 ° and 5.625 ° and a grounded ninth interference suppression filter connected through a fourth capacitor to the second input-output.

The essence of the proposed technical solution is that the mathematical modeling and experimental studies made it possible to optimize the size of the matching segment in the form of a meander with communication and together with control circuits containing noise suppressing filters, increase the working band and reduce the errors of the phase shift setting.

Comparison of the proposed solution with the known technical solutions shows that it has a new set of essential features that, together with the known features, can successfully achieve the goal.

The pin-diode discharges of 5.625 ° and 11.25 ° are combined, the matching segment of the microstrip line is made in the form of a meander with a connection, the electric length of which is ~ λ / 4 (the actual length is ~ λ / 2), which gives agreement in a wider frequency band than made in the form of a straight segment of length ~ λ / 4, as well as the implementation of phase shifts with an accuracy of ± 3 ° in the frequency band of 50%.

In FIG. 1 shows the electrical circuit of the microwave phase shifter on microstrip transmission lines of the decimeter wavelength range.

In FIG. 2 shows an example of a microwave phase shifter on microstrip transmission lines of the decimeter wavelength range.

The microwave phase shifter on the microstrip transmission lines of the decimeter wavelength range consists of: the first contact 1, the second contact 2, the matching segment of the microstrip line 3, implemented in the form of a meander with a connection, a ground circuit with an interference suppression filter 4, C ₁ -C ₄ - the first, second, third and fourth capacitors, VD ₁ -VD _{4 of the} first, second, third and fourth - pin diodes, ZR ₁ -ZR ₉ - of the first, second, third, fourth, fifth, sixth, seventh, eighth and ninth interference suppression filters.

All pin-diode discharges are made on pin-diodes of the same type (VD ₁ -VD ₄ ).

In all pin diode control circuits, block-type capacitors of the same type (C ₁ -C ₄ ) are used as blocking and isolation capacitors.

For microwave separation of the main path with control circuits of pin diode discharges 5.625 ° and 11.25 °, noise suppression filters (ZR ₁ -ZR ₈ ) are used, and an interference suppression filter (ZR ₉ ) is used with the ground circuit (4).

The operation of the microwave phase shifter on microstrip transmission lines of the decimeter wavelength range is as follows.

All pin diodes VD ₁ -VD ₄ open negative voltage. When a positive voltage is applied to contacts 1-2, all pin diodes are closed and the microwave signal passes through the main path (see, Fig. 2, the main path is shaded). We get the phase 0 °.

When a negative voltage is applied to pin 1 (see Fig. 1, 2), the pin diodes VD ₂ and VD ₃ open, and loops are connected to the main path, which ensure signal delay and phase acquisition minus 5.625 °.

When a negative voltage is applied to pin 2 (see Fig. 1), the pin diodes VD ₁ and VD ₄ open, and loops are connected to the main path, providing a delay of the microwave signal and obtaining a phase minus 11.25 °.

The presence of noise suppression filters ZR ₁ -ZR ₉ reduced the influence of the control circuits and, together with the meander with communication, expanded the working band while decreasing the phase error.

The proposed technical solution is implemented in a six-bit microstrip microwave phase shifter AFAR decimeter range. The obtained results of the technical solution:

- number of digits 2;

- the number of diodes 4;

- band of working frequencies,%, 50;

- average loss, dB, less than 0.5;

- average current consumption per discharge, mA, 60;

- phase setting error ± 3 °;

- dimensions (L × W × T), mm ³ , (14 × 20 × 1).

The technical and economic advantage of the proposed technical solution is the creation of a small-sized wideband microband microwave phase shifter on microstrip transmission lines of the decimeter wavelength range with discharges of 11.25 ° and 5.625 ° with small phase installation errors.

Claims (1)

Microwave phase shifter on microstrip transmission lines of the decimeter wavelength range, containing two combined pin diode discharges 11.25 ° and 5.625 ° on the loaded line, each with two pin diodes, characterized in that the cathodes of the pin diodes are connected to two in series connected noise suppression filters, the outputs of each discharge being combined and connected to the corresponding outputs of the control device and connected to the housing through the first capacitors, in addition, the anodes of the first two pin diodes of discharges 11.25 ° and 5.625 ° are combined and through the third the capacitor is connected to the first input-output, while the anodes of the second two pin diodes of discharges 11.25 ° and 5.625 ° are combined and connected through the matching segment of the microstrip line, made in the form of a meander with a connection, with the connected anodes of the first two pin diodes of discharges 11 , 25 ° and 5.625 ° and a grounded ninth interference suppression filter connected through the fourth capacitor to the second input-output.

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