RU2631904C1 - Restrained phase shift of microwave - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: tunable microwave phase shifter contains the first segment of the transmission line whose ends are connected to the input and output of the tunable phase shifter, to the middle of which an open section of the transmission line is connected via a jumper to which additional open line segments can be connected via jumpers. The input and output of the tunable phase shifter are further connected by a second section of the transmission line arranged parallel to the first section through the gap and equal in length to it. In the middle of the second segment of the transmission line, a break is made, two additional jumpers are connected symmetrically on both sides of the rupture, connecting the first and second segments of the transmission line through the gap, the position of which changes with adjustment, with the wave resistance of the first and second line segments being twice the input resistance.

EFFECT: reducing the error in setting the phase value and improving the matching in a wide frequency range with small dimensions.

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Description

The invention relates to the field of microwave radio engineering and can be used to adjust the phase of the transmission coefficient of microwave paths and phase alignment of microwave paths in phased antenna arrays.

A known element for adjusting the length of the line (see. Handbook for the calculation and design of microwave strip devices / Ed. By I.V. Volman. M., Radio and Communications 1982, pp. 184-185, Fig. 4.29, a). The element contains a U-shaped conductor of the line segment connecting the input and output. Gaps are made in the parallel arms of the U-shaped conductor, next to which between the shoulders of the U-shaped conductor are conductors of segments of the connecting lines. When adjusting the phase, jumpers are installed connecting the sections of the U-shaped conductor and connecting lines, so that the total length of the line between the input and output changes. The disadvantage of the element for adjusting the length of the line is a large number of jumpers. In addition, the phase is reconstructed stepwise with a discrete determined by the length of the conductor between adjacent discontinuities, which leads to a large phase adjustment error.

A smaller number of jumpers and a smaller phase adjustment error has a phase shifter (see USSR AS No. 1826091), which can be used as a tunable phase shifter when replacing switching diodes with jumpers. The phase shifter contains a dielectric plate, on one side of which there is a metal base, and on the other side - a conductor connecting the input and output. An open conductor is connected perpendicularly to one connecting conductor through a jumper at one end, the next open conductor is connected at one end through the next jumper, etc. A gap is made in the metal base, perpendicular to crossing the projection of the connecting line and open on one side after crossing. The axis of the gap coincides with the axis of the additional conductor, the length of the gap is equal to the length of the common conductor with jumpers. A jumper is connected between the edges of the slit, the position of which is determined by adjusting the phase. With a jumper located under the projection of the connecting line conductor and no jumper between the connecting line and the first open conductor, the phase is minimal and is determined by the length of the connecting line. When the jumper moves in the gap from the open end, the phase gradually increases due to the series inductance of the gap. At the same time, the VSWR slightly increases (standing wave voltage coefficient). When the first open loop is connected, the phase increases stepwise due to the parallel connection of the open conductor capacitance. In this case, the VSWR decreases and becomes minimal when the gap and loop lengths are equal. Thus, by moving the jumpers in the slit and the settings of the jumpers that extend the additional conductor, a smooth phase change occurs with a slight increase in VSWR. The disadvantages of the phase shifter are due to the presence of a slit line. These are large dimensions of the open end of the slot, the need to increase the body on the side of the metallized base of the board to ensure the operation of the slot line.

The closest known analogue to the claimed phase shifter is a loop-through phase shifter of the loaded transmission line type (see G.S. Hizh et al. Microwave Phase-shifters and Switches, M., "Radio and Communications" 1984, page 76, Fig. 2.20 ) selected as a prototype. The pass-through phase shifter contains a quarter-wave length of the transmission line connecting the input and output, at the ends of which the same reactive loads are connected, for example, in the form of an open length of the line, the length of which is stepwise changed by jumpers. The prototype phase shifter is matched only at one frequency, at which reflections from open line segments cancel each other, with a length of the connecting segment approximately equal to a quarter of the wavelength. When the detuning from the coordination frequency, the VSWR of the prototype phase shifter grows, and the more the introduced phase shift provides the prototype, the greater the increase in VSWR. Therefore, the prototype phase shifter at a given level of coordination in the operating frequency range provides small phase changes. Since the change in capacitance by means of jumpers is performed stepwise, the prototype phase shifter has a large phase adjustment error. In addition, the prototype phase shifter has large dimensions due to the use of a quarter-wave length of the line.

The technical result of the invention is to reduce the error in the installation of the phase value and improve coordination in a wide frequency range with small dimensions of the phase shifter.

The technical result is achieved by the fact that in the tunable microwave phase shifter containing the first segment of the transmission line, the ends of which are connected to the input and output of the phase shifter, to the middle of which an open segment of the transmission line is connected via a jumper, the length of which changes stepwise when adjusting the phase by setting additional jumpers between its sections characterized in that the input and output are additionally connected through a second segment of the transmission line, similar to the first segment, and located parallel to it Without a gap, a gap is made in the middle of the second segment of the transmission line, the first and second segments are additionally connected through two jumpers located symmetrically relative to the gap, the position of which changes when the phase is adjusted, while the wave resistance of the first and second segments of the transmission lines is twice as large as the input resistance .

The introduction between the input and output of the second segment of the transmission line, similar to the first, parallel to it, with a wave resistance of two times the input resistance, as well as jumpers between the segments, allows you to use the common transmission line to the jumpers as a consistent transmission line. The segments of the transmission lines between the jumpers and the connected open conductor form a phase-shifting low-frequency loop filter (low-pass filter), consistent in a wide frequency range. Changing the position of the jumpers simultaneously with changing the length of the open conductor allows you to change the phase of the transmission coefficient of the low-pass filter and, therefore, the phase shifter.

The combination of distinctive features and properties of the proposed tunable phase shifter are not known from the literature, therefore, it meets the criteria of novelty.

In FIG. 1 shows the topology of a tunable phase shifter in a microstrip design.

In FIG. Figure 2 shows the amplitude-frequency (AFC) and phase-frequency (PFC) characteristics that explain the operation of a tunable phase shifter.

The proposed tunable microwave phase shifter (see Fig. 1) contains the first segment of transmission line 1, the ends of which are connected to the input and output of the phase shifter. An open segment of line 3 is connected to the middle of a segment of transmission line 1 through jumper 2. Line segments 5, 6, 7 of different lengths, one at a time, are connected to an open segment of line 3, through additional jumpers 4.

The input and output of the tunable phase shifter are additionally connected through a segment of transmission line 8 located through a gap parallel to a segment of transmission line 1 and equal in length and width to it. A gap is made in the middle of the length of the transmission line 8, on both sides of which the segments of the transmission lines 1 and 8 are connected by two jumpers 9 and 10 located in the gap.

The widths of the conductors of the segments of the transmission line 1 and 8 are selected from the condition for obtaining the wave impedance of the line segments is twice as large as the input resistance - z ₀ .

The distance between jumpers 9 and 10 changes with phase adjustment.

The size of the gap is chosen approximately equal to the width of the length of the transmission line 1.

The length of the segments of the transmission lines 1 and 8 is less than a quarter of the wave and is determined by the magnitude of the phase shift of the tunable phase shifter.

The length and width of the line 3 segment is determined based on the minimum change in phase shift. The lengths of line segments 5, 6, 7 are multiples of the length of line 3. For example, the length of line 5 is equal to the length of line 3, the length of line 6 is two lengths of line 3, the length of line 7 is four times the length of line 3. In this case, when using jumpers 4 between segments 3, 5, 6, 7 provides a discrete change in length with a single step from one to eight.

The proposed tunable microwave phase shifter operates as follows.

In the initial state, with a minimum phase shift of the phase shifter, jumpers 2, 4 are not installed, jumpers 9 and 10 are installed at a minimum distance from each other. The microwave signal supplied to the input of the phase shifter passes through its two identical segments of transmission lines 1 and 8. Since the wave resistance of the segments of transmission lines 1 and 8 is 2z ₀ , the total wave resistance of the common transmission line is equal to the input resistance z ₀ , as a result, the phase shifter is consistent across the entire frequency range and at the same time introduces a phase shift equal to the phase of the transmission coefficient of segment 1.

With an increase in the distance between jumpers 9 and 10 and installation of jumper 2, sections of segments of transmission lines 1, 8 located between the jumpers, and a connected open segment 3 form a phase-shifting three-loop low-pass filter (LPF), matched over a wide frequency range. Moreover, since the phase of the low-pass filter transmission coefficient is greater than the phase of the line segment, the phase of the phase shifter transmission coefficient increases. When connecting 4 additional open segments 5, 6, 7 with jumpers and a corresponding increase in the distance between jumpers 9, 10, the phase of the phase shifter transmission coefficient increases while maintaining coordination. Since the jumper 9, 10 moves smoothly, the phase shifter phase can be adjusted smoothly.

Thus, by moving the jumpers 9 and 10 when connecting segments 3, 5, 6, 7, an almost smooth change in the phase of the transmission coefficient of the tunable phase shifter is provided when matching in a wide frequency range (see Fig. 2).

A mock of the proposed tunable microwave phase shifter was manufactured at the enterprise. The layout is made on a microstrip line with a phase change range at a given frequency of 45 degrees. During the experimental verification, results were obtained confirming the achievement of the goal. The layout of the tunable phase shifter in the frequency range of 70% width provides a smooth phase change, with VSWR from the input side less than 1.2. The length of the phase shifter is equal to one eighth of the wavelength. The phase shifter prototype provides only a discrete phase change in increments of 5.6 degrees, with the same VSWR in a narrow frequency range of 10%. The prototype phase shifter is a quarter wavelength long. Thus, the proposed tunable microwave phase shifter, in comparison with the prototype phase shifter, provides a reduction in the phase tuning error while expanding the matching frequency range in the frequency range by seven times. The length of the proposed tunable microwave phase shifter is two times less than that of the prototype phase shifter.

Claims (1)

A tunable microwave phase shifter comprising a first segment of a transmission line, the ends of which are connected to the input and output of a tunable phase shifter, to the middle of which an open segment of a transmission line is connected via a jumper, to which additional open segments of a line can be connected by jumpers, characterized in that the input and output tunable phase shifter additionally connected by a second segment of the transmission line located parallel to the first segment of the transmission line through the gap and equal to e along the length, in the middle of the second segment of the transmission line, a gap is made, on both sides of the gap two additional jumpers are connected symmetrically connecting the first and second segments of the transmission line through the gap, the position of which changes during adjustment, while the wave resistance of the first and second line segments is two times the input resistance.

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