RU2799991C1 - Microstrip fixed uhf phase shifter - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: microstrip fixed microwave phase shifter consists of reference (RC) and phase-shifting (FC) channels. The phase-shifting channel is formed by a cascade connection of three segments of a homogeneous single microstrip transmission line with different lengths and wave impedances. A short-circuited loop is connected in parallel to the central segment of the PC formed by a cascade connection of three segments of a homogeneous transmission line with different lengths and wave impedances. The wave impedances of the segments satisfy the following relations: Z₁<Z₀, Z₁<Z₂, Z₀≈Z₂, Z₃<Z₄<Z₅; or Z₀>Z₁>Z₂, Z₃>Z₄, Z₃ = Z₅.

EFFECT: creation of a broadband microstrip fixed microwave phase shifter having small overall dimensions with improved frequency characteristics.

1 cl, 6 dwg

Description

The invention relates to the field of radio engineering, in particular to devices for the phase shift of radio signals, and can be used to create broadband electronic equipment.

Known phase shifter with the structure of the electrical circuit of the phase-shifting channel in the form of a half-wave segment of the transmission line with wave impedance Z , loaded with open and short-circuited loops of length λ _cf /8 (where λ _cf is the wavelength in the transmission line at the center frequency of the operating range) and wave resistance Z _stub .

The advantages of this structure include ease of manufacture, and the disadvantages - a significant deviation of the phase response from the nominal value (Microwave & RF. - 1979. - No. 12. - p. 167-168).

Also known are the structures of the phase-shifting channel of fixed phase shifters based on single half-wave transmission lines with quarter-wave loops in the form of T- and U-shaped connections (Radio Engineering and Electronics. - 1988. - T.33. - C.1. - S. 63-69).

The deviation of the phase-frequency characteristic from the nominal value of phase shifters with such phase-shifting channels (FC) is reduced compared to the previous solution, however, the value of the standing wave coefficient by the voltage of the phase-shifting channel arms has significantly increased, which is the main disadvantage of these structures.

Another well-known fixed phase shifter is a class I stepped single line FK structure, which is a symmetrical cascade connection of an odd number of transmission line segments, to the central segment of which a homogeneous quarter-wave short-circuited stub is connected in parallel. The length of the central segment of the transmission line is equal to λ _cf /2, the lengths of all the others are equal to λ _cf /4. The wave impedances of the supply lines Z ₀ and segments of the transmission lines Z ₁ , Z ₂ , Z _(n+1)/2 are related by the relation: Z ₀ > Z ₁ > Z ₂ >…> Z _(n+1)/2 . This structure provides a nominal phase shift of 22.5≤ϕ ₀ ≤135 in a frequency band up to one and a half octaves wide (RF patent for utility model No. 31690, IPC H01R 1/18, publ. 20.08.2003).

The disadvantages of this fixed phase shifter include significant overall dimensions.

The closest to the proposed solution is a fixed microwave phase shifter containing a phase-shifting channel, a compensating line (reference channel) and supply lines. The structure of the electric circuit of the phase-shifting channel is made on the basis of a symmetrical single class II stepped transmission line, loaded with a quarter-wave homogeneous short-circuited loop. A single transmission line of class II is made in the form of a cascade connection of an odd number of alternating segments of homogeneous transmission lines with wave impedances Z and Z ₀ located symmetrically with respect to the central segment with resistance Z . The lengths of the segments and the tail are selected from the ratios: l ₁ <l ₃ <…<l _2n-1 ; l ₂ >l ₄ >...>l _2n-2 , l _2n-1 >l _w , where l ₁ , l ₃ , ..., l _2n-1 are the lengths of the transmission line segments with wave impedance Z , while l _2n-1 is the length of the central segment, l ₂ , l ₄ , ..., l _2n-2 are the lengths of the transmission line segments with wave impedance Z ₀ , l _w is the length of the loop. (Utility model patent of the Russian Federation No. 34036, IPC H01P 1/18, published on November 20, 2003).

However, it should be noted significant dimensions and insufficiently accurate provision of a constant phase shift in a wide frequency band.

The technical problem of the present invention is to eliminate the disadvantages of the listed designs of fixed phase shifters with a phase-shifting channel based on a single transmission line.

The technical result of the invention is a more accurate provision of a constant phase shift in a wide frequency band while reducing the maximum value of the standing wave ratio for the input voltage of the phase-shifting channel with a decrease in overall dimensions.

The technical result is achieved by the fact that in a microstrip fixed microwave phase shifter, including a reference channel in the form of a segment of a single homogeneous transmission line and a phase-shifting channel in the form of a single step-inhomogeneous line from an odd number of alternating segments of homogeneous transmission lines with a short-circuited loop included in the center of the line and supply lines, according to the solution, the lengths of the transmission line segments forming the phase-shifting channel have different lengths, different from λ _cf /2, the number of segments of the phase-shifting channel is three, a short-circuited loop is formed by a cascade connection of three segments of a homogeneous transmission line with different wave impedances, while the wave impedances of the segments satisfy the following relations:

Z ₁ <Z ₀ , Z ₁ <Z ₂ , Z ₀ ≈Z ₂ , Z ₃ <Z ₄ <Z ₅ ; or

Z ₀ >Z ₁ >Z ₂ , Z ₃ >Z ₄ , Z ₃ = Z ₅ , where

Z ₀ - wave impedance of the supply lines;

Z ₁ , Z ₂ - wave impedance of the segments of the transmission lines that form the FC;

Z ₃ , Z ₄ , Z ₅ - wave impedance of segments of transmission lines forming a short-circuited loop;

λ _cf - wavelength in the transmission line at the central frequency of the operating range.

The present invention is illustrated by illustrations: Fig. 1 shows the structure of the proposed device; in fig. 2 is a schematic model of a three-stage microstrip fixed microwave phase shifter in the T-wave approximation, FIG. 3 - phase-frequency characteristics of the device, in Fig. 4 - dependence of VSWR on frequency, in Fig. 5, 6 - options for manufacturing microwave phase shifters with different regularities in the distribution of wave impedances of transmission line segments.

Positions in the drawings indicate:

1 - reference channel (OK);

2 - phase-shifting channel (FC);

3 - single stepped transmission line (LP);

4 - short-circuited stepped loop;

5 - supply LP;

P1 - input port OK;

P2 - output port OK;

P3 - FC input port;

P4 - FC output port;

Z ₀ - wave impedance of the supply LP;

Z ₁ , Z ₂ - wave impedance of the segments of the LP, forming the FC;

Z ₃ , Z ₄ ,Z ₅ - wave impedance of the LP segments forming a short-circuited loop;

θ ₀ - electrical length of the segments of the supply LP;

θ _OK - electrical length OK;

θ ₁ , θ ₂ - electrical length of segments of the LP, forming the FC;

θ ₃ , θ ₄ , θ ₅ - electrical lengths of the segments of the LP, forming a short-circuited loop.

In a micropolitan fixed microwave of the phazor -men, the support channel 1 is made in the form of a segment of a single homogeneous transmission line, and the phase -drive channel 2 is implemented on the basis of a symmetric stepped single transmission 3, loaded with a short -term stamped train 4, while the length of the segments of the gear lines that form the phase -spraying channel have different long -range. λ _cf /2, where λ _cf is the wavelength at the central frequency of the working range. The following regularities of the distribution of wave impedances of the segments of the transmission lines of the phase-shifting channel are optimal: Z ₁ <Z ₀ , Z ₁ <Z ₂ , Z ₀ ≈ Z ₂ , Z ₃ <Z ₄ <Z ₅ , the dotted line - in the case of Z ₀ > Z ₁ > Z ₂ , Z ₃ > Z ₄ , Z ₃ \u003d Z ₅ . The distribution patterns of electrical lengths θ ₁ , θ ₂ , θ ₃ , θ ₄ , θ ₅ of the LP segments included in the PC, and the length of the reference channel θ _OK depend on the value of the nominal phase shift.

Microstrip fixed microwave phase shifter works as follows. In-phase electromagnetic waves of equal amplitude are fed through supply lines 5 to the input of the reference channel P1 and to the input of the phase-shifting channel P3, and due to the optimally selected electrical lengths and wave impedances of the segments of the stepped transmission line and loop, as well as the length of the reference channel, electromagnetic waves arise at the output ports P2, P4 of the fixed phase shifter, having a nominal phase shift relative to each other, equal to a given value. The VSWR level of the ports of the phase-shifting channel does not exceed 1.2 in the octave frequency band.

The phase-frequency characteristic of a fixed phase shifter and the frequency dependence of the voltage standing wave ratio (VSWR) of the arms of its phase-shifting channel in the octave frequency band for a nominal phase shift ϕ ₀ =45° in the T-wave approximation are presented, respectively, in FIG. 3 and FIG. 4, where the solid line is the case Z ₁ <Z ₀ , Z ₁ <Z ₂ , Z ₀ ≈Z ₂ , Z ₃ <Z ₄ <Z ₅ , the dotted line is the case Z ₀ >Z ₁ >Z ₂ , Z ₃ >Z ₄ , Z ₃ = Z ₅ .

The electrical lengths of the LP segments depend on the nominal value of the phase shift ϕ ₀ . In FIG. Figures 5 and 6 show options for implementing the FC for the nominal value of the phase shift ϕ ₀ = 45°. The electrical lengths of the LP segments in this case satisfy the following relations:

θ ₁ <θ ₂ , θ ₃ <θ ₄ , θ ₄ ≈θ ₅ ,

or θ ₁ <θ ₂ , θ ₃ ≈θ ₄ ≈θ ₅ , where

θ ₁ , θ ₂ - electrical length of segments of the LP, forming the FC;

θ ₃ , θ ₄ , θ ₅ - electrical lengths of the segments of the LP, forming a short-circuited loop.

Due to the revealed regularity in the distribution of electrical lengths and wave impedances of the transmission line segments of the phase-shifting channel, the proposed structure of the fixed phase shifter in comparison with the prototype in the operating frequency band of the same width has smaller overall dimensions with comparable values of frequency characteristics.

To confirm the results obtained, microstrip fixed phase shifters were manufactured and experimentally studied for the nominal value of the phase shift ϕ ₀ =45° and the overlap factor of the operating frequency range , the values of the wave impedances of the segments of the transmission lines which satisfy the relations Z ₁ <Z ₀ , Z ₁ <Z ₂ , Z ₀ ≈Z ₂ , Z ₃ <Z ₄ <Z ₅ (Fig. 5) and Z ₀ >Z ₁ >Z ₂ , Z ₃ >Z ₄ , Z ₃ = Z ₅ (Fig. 6) . The measured maximum value of the VSWR of the phase-shifting channels is 1.17, the deviation of the PFC from the nominal value of the phase shift does not exceed 1.16°.

Claims (6)

A microstrip fixed microwave phase shifter, which includes a reference channel in the form of a segment of a single homogeneous transmission line and a phase-shifting channel in the form of a single step-inhomogeneous line from an odd number of alternating segments of homogeneous transmission lines with a short-circuited loop included in the center of the line and supply lines, characterized in that the lengths of the segments of the transmission lines that form the phase-shifting channel have different lengths, different from, the number of segments of the phase-shifting channel is three, a short-circuited loop is formed by a cascade connection of three segments of a homogeneous transmission line with different wave impedances, while the wave impedances of the segments satisfy the following relations: Z ₁ <Z ₀ , Z ₁ <Z ₂ , Z ₀ ≈Z ₂ , Z ₃ <Z ₄ <Z ₅ ; or Z ₀ >Z ₁ >Z ₂ , Z ₃ >Z ₄ , Z ₃ = Z ₅ , where Z ₀ - wave impedance of the supply lines; Z ₁ , Z ₂ - wave impedance of the segments of the transmission lines that form the FC; Z ₃ , Z ₄ , Z ₅ - wave impedance of segments of transmission lines forming a short-circuited loop; is the wavelength in the transmission line at the center frequency of the operating range.