RU180138U1 - COMPACT THREE-LINE DIRECTED TAP - Google Patents

Abstract

The utility model relates to the field of radio engineering, namely to microwave technology and is aimed at reducing the overall dimensions of directional couplers. The technical result achieved by the implementation of the utility model is to reduce the lengths of segments of transmission lines in the directional coupler. A compact three-loop directional coupler, characterized in that it contains four input transmission lines with wave resistance, five artificial transmission lines, two microstrip transmission lines, where the first input of the fifth artificial transmission line is connected to the first input of the device and the first input of the tenth quarter-wave length of the transmission line, the second the input of the fifth artificial transmission line is connected to the first input of the sixth and seventh artificial transmission line, the second input of the sixth artificial transmission line with connected to the third input of the device and the first input of the eleventh quarter-wave length of the transmission line, the second input of the eleventh quarter-wave length of the transmission line is connected to the fourth input of the device and the first input of the ninth artificial transmission line, the second input of the ninth artificial transmission line is connected to the second input of the seventh and eighth artificial transmission line , the second input of the eighth artificial transmission line is connected to the second input of the device and the second input of the tenth quarter-wave length of the line Transferring. Preferred for the implementation of a compact design are idling loops. 2 s.p. f-ly; 3 ill.

Description

The utility model relates to microwave technology and can be used in radio devices for various purposes, for example, radar, radio navigation, communications, antenna systems, as well as a functional unit for constructing power dividers, phase shifters, mixers, modulators, discriminators, power combiners.

At present, the design of a quadrature directional coupler made in the form of two identical segments of a transmission line, for example, a coaxial cable, 1/8 wavelength in a line and containing two lumped communication capacities that are connected at the ends of the segments between potential line conductors, is widely known. (“Devices for adding and distributing the power of high-frequency oscillations.” Edited by ZI Model. Publishing House “Soviet Radio”, M. 1980. S. 86-87, Fig. 6.6). The disadvantages of this technical solution are: a narrow band of operating frequencies and a large overall size.

Another commonly used design is a quadrature directional coupler on elements with lumped parameters. The coupler is a symmetric eight-port network consisting of high-pass filters ("Broadband microwave devices on elements with lumped parameters" Karpov VM, Malyshev VA, Perevoshchikov IV - M: Radio and communication, 1984. pp. 67-72, Fig. 5.5). With a wide range of operating frequencies, this coupler contains a large number of elements, and therefore has large overall dimensions, low reliability and repeatability in serial production, high cost, and is difficult to manufacture and configure.

A microstrip three-loop directional coupler is also known, which contains a dielectric substrate, one surface of which is metallized, and two microstrip transmission lines, a central structure and symmetrical relative to the central structure lateral structures located at a quarter wavelength from each other, each structure being made as a quarter-wave length of a transmission line connected to both transmission lines. (Maloratsky L.G. Yavich L.R. Design and calculation of microwave elements on strip lines - M .: Sov. Radio, 1972-186 p.). The device ensures the passage of the signal from the input of the main line to the output and the branching of part of the power to the second output, thanks to the structures connecting the transmission lines, and electromagnetic coupling between the transmission lines. The phase shift of the voltages at the outputs of such a coupler is 90 °. The disadvantages of this microstrip three-loop directional coupler are: a significant area of the substrate that is not used is useful (in the form of two squares with sides at a quarter of the wavelength), especially at low frequencies, as well as spurious bandwidths at adjacent frequencies.

The utility model is aimed at reducing the overall dimensions of a three-loop directional coupler.

The technical result achieved by the implementation of the utility model is to reduce the lengths of segments of transmission lines in the directional coupler.

и фазой коэффициента передачи 90° на центральной рабочей частоте, десятую и одиннадцатую четвертьволновые микрополосковые линии передачи с входными сопротивлениями

, подключенные друг к другу через тройники, где

, P_отв - мощность, ответвленная в один из входов, Р_вх - мощность, подаваемая на вход направленного ответвителя, где первый вход пятой искусственной линии передачи соединен с первым входом устройства и первым входом десятого четвертьволнового отрезка линии передачи, второй вход пятой искусственной линии передачи соединен с первым входом шестой и седьмой искусственной линии передачи, второй вход шестой искусственной линии передачи соединен с третьим входом устройства и первым входом одиннадцатого четвертьволнового отрезка линии передачи, второй вход одиннадцатого четвертьволнового отрезка линии передачи соединен с четвертым входом устройства и первым входом девятой искусственной линии передачи, второй вход девятой искусственной линии передачи соединен со вторым входом седьмой и восьмой искусственной линии передачи, второй вход восьмой искусственной линии передачи соединен со вторым входом устройства и вторым входом десятого четвертьволнового отрезка линии передачи.The technical result is achieved due to the fact that the compact three-loop directional coupler contains four input transmission lines with wave resistance R ₁ , five artificial transmission lines, two microstrip transmission lines, fifth, sixth, eighth, ninth artificial transmission lines with input resistances R ₃ = R _l ⋅k and 90 ° phase transfer coefficient at the central operating frequency, seventh artificial transmission line with input impedance

and the phase of the transmission coefficient 90 ° at the central operating frequency, the tenth and eleventh quarter-wave microstrip transmission lines with input impedances

connected to each other through tees where

, P _holes - power branched to one input, P _Rin - the power supplied to the input of the directional coupler, wherein the first input of the fifth artificial transmission line coupled to the first input device and the first input of the tenth quarter wave length transmission lines, a second input of the fifth artificial transmission line connected to the first input of the sixth and seventh artificial transmission lines, the second input of the sixth artificial transmission line is connected to the third input of the device and the first input of the eleventh quarter-wave segment of the transmission line , the second input of the eleventh quarter-wave length of the transmission line is connected to the fourth input of the device and the first input of the ninth artificial transmission line, the second input of the ninth artificial transmission line is connected to the second input of the seventh and eighth artificial transmission line, the second input of the eighth artificial transmission line is connected to the second input of the device and the second input of the tenth quarter-wave segment of the transmission line.

An artificial transmission line having a phase-frequency characteristic in the required frequency band that matches the phase-frequency characteristic of the transmission line has a shorter length compared to it. Thus, the use of an artificial transmission line instead of segments of transmission lines can reduce the overall dimensions of the device.

The invention is illustrated by figures, which depict:

- figure 1 is a variant of the topology of the proposed microstrip three-loop directional coupler, implemented on a substrate with a relative dielectric constant of 4.4, and a thickness of 1 mm; top view, where 1, 2, 3, 4 - inputs of the coupler, 5-9 - artificial transmission lines, 10-11 - curved transmission lines in the form of a meander.

- in FIG. 2 - graphs of the dependence of the S-parameter modules on frequency, expressed in decibels;

- in FIG. 3 is a graph of the frequency dependence of the phase difference between the coupled and the main outputs of the coupler.

The microstrip three-loop directional coupler has four 50-ohm input transmission lines, consists of five artificial microstrip transmission lines connected to each other using tees between inputs 1 and 2, 1 and 3, 3 and 4, 2 and 4 (see Fig. 1).

Microstrip three-loop directional coupler operates as follows.

The power of a high-frequency signal (for example, with an operating frequency of 1.8 GHz) received at input 1 via artificial transmission lines 5–9 partially and curved transmission lines 10–11 enters shoulder 2, partially (due to connecting curved transmission lines in the form of a meander and artificial transmission lines ) branches into the arm 4. The results obtained as a result of the study of the prototype can be clearly seen in FIG. 2, 3. The similar implementation shown in FIG. 1, the proposed coupler provides equal power division, and the arm 3 is electrically isolated in the operating frequency range, through the use of an artificial line, providing a phase shift of 90 degrees. Also, this topology makes it possible to obtain a phase difference of 90 degrees at the center frequency, as can be seen in FIG. 3. Due to the symmetry of the proposed device, a similar reasoning is true when power is applied to any other arm.

, для стандартного волнового сопротивления R_l=50 Ом входные сопротивления будут равны

Ом R₃ = R₁⋅k = 50⋅0,707 = 35,35 Ом и

Ом.For a coupler that divides the power equally between two outputs: P _hole = 0.5 W, P _input = 1 W, then

, for a standard wave impedance R _l = 50 Ohm, the input impedances will be equal

Ohm R ₃ = R ₁ ⋅k = 50⋅0,707 = 35.35 Ohm and

Ohm.

As an additional advantage, the proposed coupler does not have spurious passbands at frequencies that are multiples of the center frequency of the operating range. The use of artificial transmission lines instead of segments of the transmission line allows for efficient miniaturization of the structure.

To confirm the feasibility of the chosen technical solution, a prototype of a utility model of a microstrip three-loop directional coupler with the following technical characteristics was made:

- standing wave voltage coefficient (VSWR) of coupler inputs not more than 1, 2;

- the amplitude imbalance between the main and associated channels of the coupler does not exceed 0.8 dB, in accordance with the data in FIG. 2;

- the phase difference between the main and associated channels differs from 90 ° by no more than ± 3 °, as shown in FIG. 3.

The occupied surface area of the substrate is not larger than that of a standard two-loop bridge operating at the same central operating frequency. The area of the compact three-loop coupler is 427 mm ² , which is 67.5% less than the area occupied by the standard coupler design.

Claims (3)

1. A compact three-loop directional coupler, characterized in that it contains four input transmission lines with wave resistance R ₁ , five artificial transmission lines, two microstrip transmission lines, fifth, sixth, eighth, ninth artificial transmission lines with input impedances R ₃ = R ₁ ⋅k and 90 ° phase gain at the central operating frequency, seventh artificial transmission line with input impedance

and the phase of the transmission coefficient 90 ° at the central operating frequency, the tenth and eleventh quarter-wave microstrip transmission lines with input impedances

connected to each other through tees where

P _holes - power branched to one input, P _Rin - the power supplied to the input of the directional coupler, wherein the first input of the fifth artificial transmission line coupled to the first input device and the first input of the tenth quarter wave length transmission lines, a second input of the fifth artificial transmission line connected to the first input of the sixth and seventh artificial transmission lines, the second input of the sixth artificial transmission line is connected to the third input of the device and the first input of the eleventh quarter-wave segment of the transmission line and, the second input of the eleventh quarter-wave length of the transmission line is connected to the fourth input of the device and the first input of the ninth artificial transmission line, the second input of the ninth artificial transmission line is connected to the second input of the seventh and eighth artificial transmission line, the second input of the eighth artificial transmission line is connected to the second input of the device and the second input of the tenth quarter-wave length of the transmission line. 2. A compact three-loop directional coupler according to claim 1, characterized in that all artificial transmission lines consist of a microstrip line and idle loops connected to it. 3. A compact three-loop directional coupler according to claim 1, characterized in that all artificial transmission lines consist of a microstrip line and short-circuit loops connected to it.

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