RU2631905C1 - Discrete phase shift - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: discrete microwave phase shifter contains the same first and second segments of the transmission line, one ends of which are connected to the input and output of the phase shifter respectively, and the other connected to each other, the input and output of the phase shifter are further connected to one ends of identical third and fourth segments of the transmission line, between the other ends of which, the first commutating diode is included. The wave resistance of the third and fourth line segments is two times higher than the resistance of the input and output. To the point of connection of the first and second segments of the transmission line, a second switching diode is connected at one terminal, the second terminal of which is connected to one end of the fifth segment of the transmission line, the second end of which is open. The length and wave impedance of the first and second segments of the transmission line are equal to the length and wave impedance of the third and fourth transmission line segments.

EFFECT: increase in the amount of phase change when the standing wave ratio is decreased.

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Description

The invention relates to the field of microwave radio engineering and can be used for discrete changes in the phase of the transmission coefficient of microwave paths and in phased antenna arrays to control the position of the beam.

Known two-position pass-through phase shifter on switched segments of transmission lines (see. Hizh G.S. and other microwave phase shifters and switches. - M .: Radio and communications, 1984, S. 30, Fig. 1.21). The phase shifter contains two segments of transmission lines of different lengths, the ends of which are connected through switching diodes to the input and output of the phase shifter. Changing the phase of the phase shifter is provided by changing the length of the signal path when switching segments. The phase shifter is consistent across the entire frequency range regardless of the magnitude of the phase change. The disadvantage of a phase shifter is a large number of diodes, which reduces its reliability. The failure of one of the diodes leads not only to an erroneous phase shift value, but also to a complete signal loss.

A smaller number of diodes and, as a result, higher reliability has a two-position loop-through phase shifter such as a loaded transmission line (see G. Khizh and other microwave phase shifters and switches. - M .: Radio and communication, 1984, p. 25, fig. . 1.15). The 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 through switching diodes, for example, in the form of a short open loop. The phase shifter is matched at the middle frequency, at which the reflections from the loads cancel each other, at a selected length of the segment, approximately equal to a quarter of the wavelength. When detuning from the matching frequency, the VSWR (standing wave voltage coefficient) of the phase shifter increases, and the more the introduced phase shift is provided by the phase shifter, the greater the increase in VSWR is, therefore the phase shifter at a given level of matching in the operating frequency range provides small phase changes. In addition, the phase shifter has large dimensions due to the use of a quarter-wave length of the line.

A larger phase shift allows you to provide a loop through phase shifter (see G. Khizh and other microwave phase shifters and switches. - M .: Radio and communications, 1984, p. 30, Fig. 1.20). The phase shifter contains the same first and second segments of the transmission line, one ends of which are connected to each other, and the other connected to the input and output of the phase shifter, between which the first switching diode is connected. A second switching diode is connected to the connection point of the first and second line segments by one terminal, the second terminal of which is connected to one end of the third segment of the transmission line, the second end of which is short-circuited. The wave resistance of the first and second segments is equal to the input resistance. The loopback phase shifter has a narrow range of matching frequencies, since when the diodes are on, a quarter-wave shunt loop is connected to the input. In addition, the azo rotator has large dimensions due to the use of a quarter-wave loop.

A wider frequency band with smaller dimensions is provided by the phase shifter (see Avt. St. USSR No. 1336138, Н01Р 1/18). The phase shifter contains the same first and second segments of the transmission line, one end of which is connected to each other, and the other is connected to the input and output of the phase shifter, between which the first switching diode and capacitor are connected in series. A second switching diode is connected to the connection point of the first and second line segments by one terminal, the second terminal of which is short-circuited. The wave resistance of the first and second segments is equal to the input resistance. A phase shifter with a length of line segments equal to one eighth of the wavelength and a normalized reactance of the capacitor equal to one provides a phase shift of only 180 degrees.

The closest known analogs to the claimed discrete phase shifter is a discrete loop-shaped diode microwave phase shifter link (see RF Patent No. 2231175) for the implementation of small discrete phase changes selected as a prototype. The prototype phase shifter contains the same first and second segments of the transmission line, one ends of which are connected to each other and form a loop, and the other are connected to the input and output of the phase shifter, which are additionally connected through the same third and fourth line segments, between which a switching diode is connected. In this case, the wave resistance of the third and fourth line segments is two times higher than the input and output resistance and wave resistance of the first and second line segments and the input and output resistance.

Phase shifter-prototype does not provide a preset value of the phase shift while ensuring coordination both when the switching diode is turned on and off. When the diode is off, two open loops formed by high-resistance third and fourth line segments located at a distance equal to the total length of the first and second segments are included in the transmission line. Matching is only possible with a loop length equal to a quarter of the wavelength. In this case, when the diode is on, the communication line is shunted by a loop, which for small lengths of the third and fourth line segments is equivalent to an open loop with a length equal to the length of the first line segment. Phase shifter-prototype provides an acceptable level of coordination with a small loop length, i.e. provides small phase shifts of up to 45 degrees only in a narrow frequency range (7%).

The aim of the invention is to increase the magnitude of the phase change while reducing the coefficient of the standing wave in a wide frequency range.

To achieve this goal, a discrete microwave phase shifter is proposed, containing the same first and second segments of the transmission line, the first end of the first transmission line segment is connected to the input of the phase shifter, the second end is connected to the first end of the second transmission line segment, the second end of which is connected to the output of the phase shifter, the input and the output is additionally connected in series through the same third and fourth line segments, between which the first switching diode is connected, while the wave impedance of the third and four Werth line segments is twice the input and output impedance. According to the invention, a second switching diode is connected to one junction point of the first and second line segments. The second terminal of this diode is connected to the first end of the fifth segment of the transmission line, the second end of which is open. The length and wave resistance of the first and second segments are chosen equal to the length and wave resistance of the third and fourth segments of the line.

Performing segments of the transmission line with the same impedance, twice the resistance of the input and output, allows you to connect the first diode to connect the input to the output through an agreed transmission line with a minimum phase shift. The introduction of an additional diode with an open line segment allows you to connect the input and output through the matched low-frequency loop filter when it is turned on and off, while the phase shifter introduces the maximum phase shift.

The combination of distinctive features and properties of the proposed device from the literature are unknown, therefore, it meets the criteria of novelty.

In FIG. 1 shows a diagram of a discrete microwave phase shifter,

In FIG. 2 - amplitude-frequency characteristic (AFC) of the VSWR and phase-frequency characteristic (PFC) of a discrete microwave phase shifter. The solid lines are the frequency response and phase response in the minimum phase mode, the dashed lines are the frequency response and phase response in the maximum phase mode.

The proposed discrete microwave phase shifter (see Fig. 1) contains the first 1 and second 2 segments of the transmission line. The first end of the transmission line segment 1 is connected to the input of the phase shifter, the second end of the transmission line segment 1 is connected to the first end of the transmission line segment 2, the second end of the segment 2 is connected to the output of the phase shifter. The third and fourth and fourth 4 segments of the transmission line are additionally connected to the input and output of the phase shifter respectively, between the other ends of which the first switching diode 5 is connected. At the connection point of the first 1 and second 2 segments of the transmission line, the second switching diode 6 is connected with one terminal, the second terminal which is connected to one end of the fifth segment 7 of the transmission line, the second end of which is open.

The wave resistance of segments of the transmission line 1, 2, 3, 4 is two times greater than the input and output resistance of the phase shifter - Z ₀ , while matching the phase shifter in the minimum phase mode is ensured.

The lengths of the segments of the transmission line 1, 2, 3, 4 are the same and are determined by the introduced phase shift of the phase shifter and at the same time they are less than a quarter of the wavelength at the operating frequency.

The length and impedance of the fifth segment 7 of the transmission line are determined from the condition of matching the phase shifter in maximum phase mode. For example, when the wave impedance of the fifth segment 7 is equal to the resistance of the input and output Z ₀ , its length is approximately equal to the length of the segment 1.

The proposed discrete microwave phase shifter operates as follows.

With open diode 5 and closed diode 6, the microwave signal fed to the input of the phase shifter passes to its output along two identical paths - segments 1, 2 and segments 3, 4. Since when the wave impedance of the segments is 2Z ₀ , the total wave resistance the transmission line from input to output is equal to the input resistance Z ₀ , the phase shifter is consistent in the entire frequency range, while introducing a minimum phase shift equal to the phase of the transmission coefficient of two segments 1 and 2 or two segments 3 and 4.

With open diode 6 and closed diode 5, the microwave signal supplied to the input of the phase shifter passes through two segments of the transmission line 1 and 2, while open segments 3 and 4 are connected to the input and output of the phase shifter, and at the connection point of segments 1 and 2, an open segment of the transmission line 7 is connected. This is a low-frequency loop filter, the coordination of which for any identical lengths of segments 1, 2, 3, 4 is ensured by the length of segment 7, and the phase of the transmission coefficient of which is determined by the lengths of segments 1, 2 and lengths of segments 3, 4 , 7. Moreover, he and more phase transfer coefficient than when the open diode 5 and the closed diode 6.

Thus, when the state of diodes 5 and 6 changes, the phase of the transmission coefficient increases, when matched in a wide frequency range. The magnitude of the phase change (see Fig. 2) can be implemented from zero to 90 degrees, with good coordination in a wide frequency range.

At the enterprise, mock-ups of the proposed discrete microwave phase shifter L - frequency range were manufactured. The models are made on a microstrip line with a phase change discrete at a given frequency equal to 11.25, 22.5, 45.0, 90.0 degrees. During the experimental verification, results were obtained confirming the achievement of the goal. Layouts in the frequency range of 70% width provided switching of phase discrete with VSWR from the input side less than 1. 2. At the same time, the prototype phase shifter provided switching of discretes up to 45 degrees with higher VSWR in the frequency range of 7%. Thus, the proposed discrete microwave phase shifter in comparison with the prototype provides an extension of the range of phase adjustment in two when the expansion of the frequency range of matching more than ten times.

Claims (1)

A discrete microwave phase shifter containing the same first and second segments of the transmission line, one ends of which are connected to the input and output of the phase shifter, respectively, and the other are interconnected, the input and output of the phase shifter are additionally connected to one end of the same third and fourth segments of the transmission line, between the other the ends of which the first switching diode is turned on, while the wave resistance of the third and fourth line segments is two times higher than the input and output resistance, characterized in that to the point the connection of the first and second segments of the transmission line is connected by one terminal to a second switching diode, the second terminal of which is connected to one end of the fifth segment of the transmission line, the second end of which is open, while the length and wave resistance of the first and second segments of the transmission line are equal to the length and wave resistance of the third and fourth segments of the transmission line.

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