RU2717386C1 - Spiral ultra-wideband microstrip quadrature directional coupler - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to microwave engineering and specifically to quadrature directional couplers. Spiral ultra-wideband microstrip quadrature directional coupler has two electromagnetically connected microstrip transmission lines made in form of a flat two-coil spiral located on a dielectric substrate, the reverse side of which is completely metallized. Coupler has cascade connections of eight areas with different communication level and has functional possibility of equalizing the phase velocity of propagating waves at different frequencies, at that one spiral is turned relative to the other one around their common centre. Gaps between connected coupler transmission lines, as well as transverse dimensions of connected lines are non-uniform, varying from section to section.

EFFECT: technical result is higher efficiency of use of useful area of dielectric substrate and reduced overall dimensions of device, wider band of operating frequencies.

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Description

The invention relates to microwave technology, and in particular to communication devices such as waveguides, consisting of two connected lines, and can be used in radio devices for various purposes as an element base of thin-film integrated high-frequency nodes, such as: separation-summing devices, microwave power amplifiers, taps, radio frequency multiplexers, phase shifters, filters and others.

The relevance of this technical solution is due to the increasing requirements for high-frequency nodes of communication and radar systems with regard to their broadband, miniaturization and manufacturability. To meet the current requirements, it is necessary to implement planar directional couplers and microwave power dividers / combiners with a relative passband of more than 0.60 (more than an octave) with a high yield rate.

Directional couplers are widely used in microwave technology. The main purpose of the directional couplers is the directional branching of some part of the high-frequency energy from the main path to the auxiliary one. The peculiarity of this device is that it branches a wave of only one direction, that is, propagating only in the forward or only in the opposite direction in the main path. His work is based on the excitation in the auxiliary path of several waves displaced in phase so that the amplitudes of the waves propagating in the desired direction, interfering, are summed up, and in the undesirable one are mutually compensated. In other words, a directional coupler (BUT) is a four-arm device consisting of two segments of a transmission line, in which part of the energy of the electromagnetic wave propagating in the main transmission line (main channel) is coupled through communication elements to an auxiliary transmission line (auxiliary channel) and transmitted in it in a certain direction. According to the degree of communication between the main and auxiliary channels, directional couplers are divided into two types: a) with strong coupling (communication less than 10 dB); b) with weak coupling (communication greater than 10 dB). In 3 dB, when a microwave signal is applied to one of its inputs, its power is distributed evenly between a certain pair of outputs and to the fourth arm, called “isolated” or “decoupled”, the power is not supplied (it is assumed that all outputs are loaded on matched loads ) It should be noted that a pair of outputs of 3 dB BUT, between which power is distributed, also has a mutual isolation.

In order to reduce the overall dimensions of the directional couplers and increase the manufacturability of their manufacture, they are structurally performed on microstrip lines - asymmetric strip transmission lines for transmitting electromagnetic waves in air or, as a rule, in a dielectric medium (substrate), along two or more thin-shaped conductors strips and plates. The lines are called microstrip, because as a result of the high dielectric constant of the substrate, its thickness and the transverse dimensions of the strip are much less than the wavelength in free space. A quasi-TEM wave propagates in the microstrip line and electric field lines pass not only in the dielectric, but also outside it. The advantages of a microstrip line and various devices based on it should also include the possibility of automating production using technologies for the manufacture of printed circuit boards, hybrid and film integrated circuits.

Known in FIG. 1 microstrip directional coupler (Maloratsky L.G. Yavich L.R. "Design and calculation of microwave elements on strip lines", M. Sov.radio, 1972, Fig. 2.14, b). The coupler contains two electromagnetically coupled lines that are formed parallel to each other on a dielectric substrate. In the coupler under consideration, the phase shift between the vectors of the electric field strength at the outputs 3 and 2 of the arms is 90 °, and therefore such couplers are called quadrature. The coupler can be made by thin-film technology on substrates of the type "Polikor", "22XC", etc. The broadband of the specified coupler is determined by the achievable coupling coefficient, the value of which depends on the gap between the electromagnetically coupled microstrip lines formed on one side of the dielectric substrate. For ceramics of the Polikor type with a relative permittivity ε _r = 10 with a wave impedance of the path ρ _about = 50 Ohms, its value does not exceed 0.5, which corresponds to a level of 6 dB on a logarithmic scale. As a result, the broadband of the described coupler is characterized by a band size of 22-25%, which is acceptable only for narrow-band devices.

Also shown in FIG. 2 tandem microstrip directional coupler (L. Maloratsky, “Microminiaturization of microwave elements and devices.” M. Sov. Radio, 1976, Fig. 2.16). This coupler is essentially a functional unit consisting of two identical microstrip couplers described above. Due to a certain order of connecting the poles of these couplers, it is possible to realize a "tandem" microstrip coupler with a passband of 60-65%. However, both generatrices of the coupler should not have direct electromagnetic coupling with each other, which makes it practical to distribute them on the substrate at noticeable distances, which increases the dimensions of the tandem coupler as a whole and limits its scope in microwave technology.

Closest to the essence of the claimed invention is shown in FIG. 3 tandem directional coupler (A. Lekhtsier, AN Fedosov, “Tandem directional couplers and nodes based on them”, Radio Industry Magazine, Moscow, 2004, pp. 148-154, Fig. 6). This coupler is essentially the tandem coupler described above (see FIG. 2), however, the lateral communication lines (BLS) of this coupler are of zero length. In this case, the microstrip transmission lines are formed in the form of a flat two-way spiral with one turn. To output signals from the center of the spiral to the outside, jumpers are used. Small capacitances can be installed at the input and output points of such a coupler to reduce losses at the edges of the operating range. Due to these solutions, the expansion of the working band is achieved in comparison with the tandem couplers described above.

However, a common drawback of the known designs of tandem couplers is that the working band is usually limited to 1.5 octaves, and the increase in communication between connected lines due to the reduction of the gaps leads to a deterioration of the standing wave coefficient (SWR) of the output arms, as well as to a significant the difference in the amplitudes of the signals in the output arms at the center frequency.

The technical result achieved by the claimed invention is to increase the efficiency of use of the useful area of the dielectric substrate and to reduce the overall dimensions of the device, to expand the band of operating frequencies.

The technical result is achieved in that the spiral ultra-wide microstrip quadrature directional coupler contains two electromagnetically coupled microstrip transmission lines made in the form of a flat two-way spiral located on a dielectric substrate, the reverse side of which is partially or completely metallized, or suspended above a metal surface. The coupler is characterized in that the number of turns of the two-way spiral is more than one, with one spiral being rotated relative to the other around their common center, while the gaps between the connected transmission lines of the coupler formed in the form of a two-way spiral in which one spiral is rotated relative to the other around their common center , as well as their transverse dimensions, vary from section to section of connected lines.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 shows a microstrip directional coupler known from: L. Maloratsky Yavich L.R. "Design and calculation of microwave elements on strip lines", with the transverse dimension W of the microstrip lines and with a gap g between them. The conclusions (shoulders) of the coupler are hereinafter indicated in the following sequence: 1 - input, 2 - branched output, 3 - direct output, 4 - decoupled output.

In FIG. 2 shows a tandem microstrip directional coupler known from: L. Maloratsky “Microminiaturization of microwave elements and devices”, with a transverse dimension W of microstrip lines and a gap g between them. To connect the segments of microstrip lines, jumpers 5 are used.

In FIG. 3 shows a tandem directional coupler, known from: Lehtsier A.Ya., Fedosov A.N. "Tandem directional couplers and nodes based on them", in which the microstrip transmission lines are formed in the form of a flat two-way spiral with one turn. Jumpers 5 are used to output signals from the center of the spiral.

In FIG. Figure 4 shows a top view of the coupler with transmission lines formed in the form of a two-way spiral with variable transverse dimensions W1, W2, W3 of connected lines and gaps g1, g2, g3 between them at different parts of the two-way spiral, with angles of rotation of planar lines of 90 degrees. To output signals from the center of the spiral, jumpers 5 are used.

In FIG. 5 shows eight main communication areas of the coupler of FIG. 4. Areas K5 and K6 have three connected lines, areas K7 and K8, have two strongly connected lines, and areas K9, K10, Kl1 and K12 each have two weakly connected lines.

Presented in FIG. 4 variant of the formation of connected lines in the form of a two-way spiral does not exhaust all possible options. So, for example, a two-way spiral can be formed from planar lines rounded along its entire length.

In FIG. Figure 6 shows graphs of the dependence of the calculated transmission coefficients on the frequency of the tandem and spiral couplers with constant and varying transverse dimensions of the connected transmission lines and the gaps between them (with regular and irregular structure, respectively), loaded by 50 Ohms, when dividing / adding.

In FIG. 7 is a diagram of division / summation of 3-dB couplers 6 loaded to a matched load.

The design of the directional coupler is based on the use of two electromagnetically coupled microstrip transmission lines formed in the form of a flat two-way spiral with more than one number of turns, while one spiral is rotated relative to the other around their common center. To output signals from the center of the spiral, one can use, as shown in FIG. 4 jumpers 5 (wire, foil, hybrid grown or another type).

At its core, such a coupler is a tandem connection of many segments of connected lines, which is one of the known methods for expanding the working frequency band of tandem directional couplers (tandem switching of coupled lines is described in the work: V.P. Meshchanov, A.L. Feldstein “Automated design of directional microwave couplers ”,“ Communication ”, Moscow, 1980, pp. 96-97). For example, in FIG. 4 and FIG. 5 shows a variant of the topology of the claimed coupler with uneven gaps between the communication lines gl, g2, g3 and their uneven width (cross section) Wl, W2, W3. At its core, a spiral coupler with such a structure, as well as a spiral coupler with a regular structure, is a tandem connection of many segments of connected lines, which is one way to expand the working strip of tandem directional couplers. In FIG. 5 shows eight main communication areas of such a coupler. Regions K5 and K6 have three connected lines, K7 and K8, have two tightly connected lines and regions K9, K10, K11 and K12, and have two weakly connected lines. In addition, due to changes in the transverse dimensions of the transmission lines and the gaps between them, depending on the angular coordinate, the phase velocity of the propagating waves at different frequencies is equalized. The cascade connection of eight regions with different communication levels in a coupler with such an irregular structure allows us to more significantly expand the band of its operating frequencies (up to 3.5 octaves) compared with the variant considered above.

In FIG. Figure 6 shows the graphs of the estimated loss per division / summation of three types of 3 dB couplers in the 1-6 GHz band, one arm of which is loaded on a matched load. The division / summation measurement circuit is shown in FIG. 7.

Due to the folding of electromagnetically coupled lines into a spiral, the overall dimensions of the coupler, in comparison with the prototype, are reduced by at least two to three times (inversely proportional to the number of turns in the two-way spiral), which significantly increases the efficiency of using the useful area of the substrate.

Thus, the essential features of this technical solution can significantly expand the range of operating frequencies of the coupler, reduce its overall dimensions and increase the efficiency of using the useful area of the substrate, which ensures the achievement of the claimed technical result.

Claims (1)

A spiral ultrawide microstrip quadrature directional coupler containing two electromagnetically coupled microstrip transmission lines made in the form of a two-way flat helix located on a dielectric substrate, the reverse side of which is completely metallized, while the coupler has cascade connections of eight regions with different communication levels and has the ability to align phase velocity of propagating waves at different frequencies, with one spiral wrapped relative to another around their common center, and the gaps between the coupled coupled transmission lines, as well as the transverse dimensions of the connected lines, are uneven, varying from site to site.

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