RU2601533C1 - Power divider - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to radio engineering, particularly to power dividers. Device comprises an input arm connected through quarter-wave sections of the transmission lines to two output arms. Between the output arms there is a ballast decoupling resistor made in the form of a section of the transmission line with losses. Resistor middle point is connected to a short-circuited loop conductor with the length less than a quarter wavelength of the central frequency of the operating range. Section of the transmission line with losses is made nonuniform in the form of two identical contacting discs. Herewith the width of the discs coupling section is equal to the width of the said short-circuited loop conductor, the width of the coupling sections of the ballast decoupling resistor with the quarter-wave sections of the transmission lines is equal to the width of these sections. Sections of the ballast resistor coupling with the quarter-wave sections of the transmission lines and with the short-circuited loop conductor are located on extension of a straight line connecting centers of the said discs.

EFFECT: improved isolation between arms of the divider and matching at its input and outputs.

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Description

The invention relates to microwave technology and can find application in systems of active phased antenna arrays, radio transmitting and other devices and microwave systems.

A known power divider containing a splitter, the outputs of which are connected ballast decoupling resistors connected by a star (Wilkinson EJ An N-hybrid power divider // IRE Trans, on microwave theory and techniques. 1960. v. MTT-8, N 1. p. 116-118). This initial scheme of the power divider is basic, since on its basis a large number of options have been proposed that ensure the achievement of higher technical characteristics, the expansion of the device's application areas and the solution of other, including new, problems. A power divider with two output arms and, respectively, with two quarter-wave segments of the transmission line in the splitter, between which a ballast decoupling resistor is connected, is widely known in the literature (see Maloratsky L.G., Yavich L.G. Design and calculation of microwave elements on strip lines . - M.: Soviet Radio, 1972. - 232 s).

A known power divider comprising a segment of an input transmission line connected by quarter-wave line segments with two output arms between which a ballast load is connected, characterized in that in order to expand the working frequency band and increase the isolation, the ballast load is made in the form of two resistors, between which is further included half-wave segment of connected lines closed at the end (see. Power divider, ed. certificate of the USSR No. 496625, H01P 5/12, BI No. 47. 04/23/76).

When operating at a high power level, the area of the ballast resistors in the film version and, as a result, their parasitic parameters increase, which leads to a sharp deterioration in the technical characteristics of the device - matching of inputs and outputs, decoupling between them, lower direct transmission coefficient, increased loss in ballast resistors, frequency offset of the VSWR minima and the isolation maximum, etc. (see K.Ya. Aubakirov, V.I. Govorukhin, L.G. Plavsky, M.G. Rubanovich. Two-channel common-mode totalizer-power divider with compensation parasitic parameters of the ballast resistor. - Radio engineering, No. 6, 2011, pp. 59-63). In addition, the introduction of a closed at the end of a half-wave segment of connected lines complicates the scheme and increases the dimensions of the device.

A known power divider (see. Power addition device, ed. Certificate of the USSR No. 1170534, НРР 5/12, BI No. 28. 07.30.85), containing input arms, each of which is connected to a ballast resistor and a quarter-wave length of the transmission line, with the ballast resistors are connected to a star, the ends of the quarter-wave segments of the transmission lines are connected to the output arm, characterized in that a short-circuited quarter-wave loop is connected to the common point of the ballast resistors. The suppression of the even harmonics of the summed generators is successfully performed at the center frequency of the range for which the input impedance of the quarter-wave loop is infinitely large, and therefore this loop does not affect the operation of the device. In this case, the even harmonics of the summed generators are shorted to ground, since for them the length of the loop is not a quarter, but a half-wave or a multiple of it, and the input impedance of such a loop is zero. As in the previous case, achieving high values of technical characteristics cannot be implemented in this device.

A power divider is also known (see ed. Certificate of the USSR No. 849342, H01P 5/12, BI No. 27. 07.25.81), containing a splitter, to the outputs of the shoulders of which are decoupling resistors connected by a star, characterized in that the input and short-circuited loops are connected to each of the outputs of the arm of the splitter, and a capacitor is connected to each arm of the splitter, and the capacitor capacitance and the length of each of the short-circuited loops are determined respectively from the relations

where n is the number of shoulders;

f ₀ - central frequency of the operating band;

R ₀ is the output impedance of each arm of the divider;

₀ λ - wavelength in the power divider;

ρ - wave impedance of a short-circuited loop.

Reducing losses and reducing the dimensions of the device is achieved by equivalent replacement of the transforming segments of the transmission line of the splitter with U-shaped semi-distributed links composed of two short-circuited loops in parallel branches and a concentrated capacitance in the serial branch of each P-link. However, the choice of P-link elements according to the above ratios does not allow to compensate for the deterioration of the technical characteristics of a high-power device with an increased area of ballast resistors in a film version. As in previous cases, the achievement of high values of these technical characteristics cannot be implemented in this device.

In addition, a power divider is known (see ed. Certificate of the USSR No. 1798840, H01P 5/12, BI No. 8. 02/28/93), which is a prototype of the invention and contains an input arm connected through quarter-wave segments of the transmission line to the output arms, at the same time, ballast resistors are connected between the output arms, connected to a star and to a common point of which a short-circuited loop is connected, while ballast resistors are made in the form of segments of a transmission line with losses, the loop length is selected less than a quarter of the wavelength of the central frequency of the range, and its input impedance is selected from the relations:

where Z _C , L is the impedance and the length of the length of the transmission line with losses;

γ is the propagation constant in the lossy line;

Ζ _w , l _w - wave impedance and length of the loop.

For a power divider with two output arms, the ballast decoupling resistor is made in the form of a segment of a transmission line with losses, to the midpoint of which is connected a short-circuited loop with a length less than a quarter of the wavelength of the central frequency of the operating range. This loop compensates for the parasitic parameters of the ballast resistor and improves the isolation between the output arms of the power divider, matching on its input and outputs, increases the direct transmission coefficient and, as a result, the operating power.

However, despite a significant improvement in the indicated technical characteristics of the divider, their values are not high enough, which primarily concerns the decoupling between its output shoulders and the coordination of the inputs and outputs. As a result, the use of the device in modern electronic equipment does not allow to ensure high performance characteristics of the equipment as a whole.

The objective (technical result) of the present invention is to increase the isolation between the output arms of the power divider and improve coordination on its input and outputs.

The problem is achieved in that in a power divider containing an input arm connected through quarter-wave segments of transmission lines to output arms, between which a ballast decoupling resistor is included, made in the form of a segment of a transmission line with losses, to the midpoint of which a short-circuited loop less than a quarter long is connected the wavelength of the center frequency of the working range, the specified segment of the transmission line with losses made inhomogeneous in the form of two identical contacting circles, the width of the since the interfaces of which are equal to the width of the aforementioned short-circuited loop, while the width of the sections of the interface of the ballast decoupling resistor with the quarter-wave segments of the transmission lines is equal to the width of these segments, the aforementioned sections of the interface of the ballast and the quarter-wave segments of the transmission lines and with the short-circuit cable are located on the continuation of the straight line connecting the centers circles.

In FIG. 1 shows an electrical schematic diagram of the proposed power divider; in FIG. 2 - the proposed ballast decoupling resistor; in FIG. 3 - frequency dependences of the parameters of the power divider with the proposed design of the ballast decoupling resistor, in FIG. 4 - frequency dependence of the parameters of the power divider prototype.

The power divider (Fig. 1) contains an input arm 1 connected through quarter-wave segments of the transmission line 2 to two output arms 3, between which a ballast decoupling resistor 4 is included, made in the form of a segment of an inhomogeneous transmission line with losses in the form of two identical contacting circles 5, to the interface section 6 of which a short-circuited loop 7 is connected (Fig. 2). The width of the interface 6 is equal to the width of the loop 7. The interface 8 of the ballast 4 with the quarter-wave segments of the transmission lines 2, with a width equal to the width of these segments 2, as well as the said interface 6 are located on the extension of a straight line 9 connecting the centers 10 of the circles 5 The output arms 3 of the divider are loaded on the load resistance 11.

The power divider operates as follows. When the input microwave signal arrives at the input arm 1, its power is evenly distributed through the same quarter-wave segments of the transmission lines 2 along the two output arms 3, so that with the same and matched load resistances 11, these powers on all output arms 3 are equal in phase and in phase. For the case of a minimum area of the ballast resistor, the power divider is a symmetrical six-terminal device and at the center frequency it is completely matched, and its outputs are almost perfectly decoupled. In high power devices, it is necessary to use a ballast resistor with a large area to dissipate significant power in the event of a mismatch or failure of one of the loads. In this case, the parasitic parameters of the resistor are proportionally increased, first of all, its parasitic capacitance, which leads to a sharp deterioration of the isolation between the output arms, matching of inputs and outputs, a decrease in direct transmission, an increase in losses in the ballast resistor, a frequency shift of the VSWR minima and the isolation maximum, etc. Compensation for this undesirable effect is achieved by connecting to the midpoint of the ballast decoupling resistor a short-circuit loop with a length less than a quarter of the wavelength of the center frequency of the working of a range, as is done in the prototype power divider (see K.L. Aubakirov, V.I. Govorukhin, L.G. Plavsky, M.G. Rubanovich. Two-channel common-mode adder-power divider with compensation of parasitic parameters of the ballast resistor . - Radio Engineering, No. 6, 2011, pp. 59-63). Despite a significant improvement in technical characteristics, their values are not high enough, which, first of all, concerns the isolation between the output arms and the coordination of the input and output of the device.

In the proposed power divider, increasing the isolation between the output arms and improving the matching of the inputs and outputs is achieved by using as a ballast decoupling resistor a piece of an inhomogeneous transmission line with losses in the form of two identical contact circles (Fig. 2). Indeed, the redistribution of the parasitic capacitance along the length of the ballast decoupling resistor, made in the indicated form, in comparison with a similar segment of a homogeneous transmission line with losses in the prototype power divider, allows to increase the isolation between the output arms of the divider and improve the matching of its input and outputs.

Ом. Балластный развязывающий резистор выполнен на подложке из поликора толщиной h=1 мм в виде отрезка неоднородной линии передачи с потерями в форме двух идентичных соприкасающихся кругов (фиг. 2), при этом их общая площадь равна 32 мм², как и в делителе мощности-прототипе с балластным резистором в виде отрезка однородной линии передачи с потерями прямоугольной формы размерами 4*8 мм² и той же площадью 32 мм² (см. вышеуказанную статью К.Я. Аубакиров, В.И. Говорухин и др.…). Одинаковые площади балластных резисторов в обоих сопоставляемых делителях мощности обеспечивают одинаковое значение паразитных емкостей балластных резисторов. Корректирующие короткозамкнутые шлейфы выполнены также на поликоре с шириной полоска w=0.2 мм (ρ_шл=90 Ом), расчетные значения длин шлейфов l_шл=5.45 мм на фиг. 2 и l_шл=6.2 мм для делителя мощности-прототипа.The calculated frequency dependences of the technical characteristics of the power divider in the proposed embodiment are shown in FIG. 3. The quarter-wave segments of transmission lines represented by lines idealized with air dielectric ε _r = 1 length 75 mm and the wave impedance $$\rho =R_0\sqrt{n}=\mathrm{fifty}\sqrt{2}=70.71$$

Ohm. The ballast decoupling resistor is made on a polycor substrate of thickness h = 1 mm in the form of a segment of an inhomogeneous transmission line with losses in the form of two identical contact circles (Fig. 2), while their total area is 32 mm ² , as in the prototype power divider with a ballast in the form of a segment of a homogeneous transmission line with rectangular losses of 4 * 8 mm ² and the same area of 32 mm ² (see the above article by K.Ya. Aubakirov, V.I. Govorukhin and others ...). The same area of the ballast resistors in both compared power dividers provide the same value of parasitic capacitances of ballast resistors. Short-circuited corrective loops were also made at a polycor with a strip width w = 0.2 mm (ρ _Шл = 90 Ohm), the calculated values of the loop lengths l _Шл = 5.45 mm in FIG. 2 and l _SHL = 6.2 mm for the power divider prototype.

A comparison of the dependencies in FIGS. 3 and 4 shows:

- parameter | S ₂₃ |, characterizing the isolation between the output ports, increased by 44.23 dB in comparison with the prototype power divider, the bandwidth at -25dB level expanded to 50.3 MHz or 11.5%;

- a parameter characterizing the quality of matching at the input and outputs of the power divider, as you know, is the standing voltage wave coefficient (VSWR), respectively, at the input of VSWR ₁ , at the outputs of VSWR _2,3 , the admissible value of which VSWR = 1.2 determines the device matching bandwidth by this parameter. For the proposed power divider, the matching band at the input of VSWR ₁ , at level 1.2, expanded by 75.4 MHz or 15% compared with the prototype device. A similar expansion of the matching band for the outputs of VSWR _2.3 at the same level 1.2 was 83.07 MHz, or 27% more. The minimum value of VSWR _2.3 also improved slightly from 1.144 at a frequency of 916.8 MHz for the prototype device to 1.116 at a frequency of 1025.5 MHz for the proposed power divider. We also note a significant improvement in the symmetry of the frequency dependences of these characteristics in the proposed device.

Thus, the use of a section of an inhomogeneous transmission line with losses in the form of two identical contiguous circles as a ballast decoupling resistor made it possible to increase the isolation by 44.23 dB, expand the isolation bandwidth by 11.5%, and improve the matching of the inputs and outputs of the proposed power divider, which expanded the band coordination on entry by 15%, on outputs by 27%.

Claims (1)

A power divider comprising an input arm connected through quarter-wave segments of the transmission line to two output arms, between which a ballast decoupling resistor is made, made in the form of a segment of the transmission line with losses, to the midpoint of which there is a short-circuited loop less than a quarter of the wavelength of the central frequency of the operating range characterized in that the specified segment of the transmission line with losses is made heterogeneous in the form of two identical contacting circles, the width of the interface to toryh equal to the width of said short-circuit loop, wherein the width of the portions conjugation ballast decoupling resistor quarter-wave segments of transmission lines equal to the width of the segments, said sections mating ballast with quarter-wavelength transmission lines and squirrel stub located on the extension of a straight line connecting the centers of said circles.

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