EP0986123A2 - Transition between two square waveguides rotated through 45 - Google Patents

Abstract

The waveguide coupling is provided by one or more round and/or rectangular hollow waveguide sections (5,6,7) inserted between 2 rectangular hollow waveguides (1,2) rotated through 45degrees relative to one another. The hollow waveguide sections have an inner diameter which does not exceed the inner diameter of both waveguides to be coupled.

Description

State of the art

The present invention relates to a transition between two around a common longitudinal axis at 45 ° to each other twisted square waveguides. With such a transition is fed into a square waveguide Basic wave type of a horizontal or vertical Polarization into two equal signal components Basic wave types on the other rotated by 45 ° Split square waveguide. As from the book "Waveguide Components for Antenna Feed Systems: Theory and CAD ", Artech House, Boston-London, 1993, page 423. such a transition causes a 3dB power split and e.g. therefore with an additional polarizer for the conversion of a linear polarization into a circular one Polarization can be used. According to the above Publishing occurs the transition between the two Square waveguides by a mutual Cross-section intersection. This form of transition between two square waveguides rotated against each other by 45 ° only through special, complex, high costs Manufacturing processes (e.g. galvanoplastic or eroding) producible.

The invention is therefore based on the object Transition of the type mentioned at the beginning, which with is as simple as possible to produce.

Advantages of the invention

The task mentioned is alternatively either with the Features of claim 1 or claim 3 or of Claim 5 solved.

According to claim 1 is between the two square waveguides a round waveguide section available, the one Internal cross-sectional dimensions of both square waveguides are not has inner diameter exceeding. In a Further training can be in the direction of the longitudinal axis Round waveguide section at least one other Round waveguide section with a different inner diameter connect, which also has the internal cross-sectional dimensions does not exceed either square waveguide.

According to claim 3 are between the two Square waveguides two in the direction of the longitudinal axis lined up square waveguide sections with rounded corners available. Each of the two is there Square waveguide sections rotated about the longitudinal axis so that its side walls are parallel to the side walls of it directly adjacent square waveguide are aligned, and the internal cross-sectional dimensions of each Square waveguide sections do not exceed that Internal cross-sectional dimensions of the one directly adjacent to it Square waveguide. In a further education can between the two square waveguide sections at least one Round waveguide section inserted, the Inside diameter is the inside cross-sectional dimensions of the two Square waveguide sections does not exceed.

According to claim 5 are between the two Square waveguides in the direction of the longitudinal axis Round waveguide section and a square waveguide section strung together with rounded corners. The Square waveguide section is rotated about the longitudinal axis so that its side walls are parallel to the side walls of it directly adjacent square waveguide are aligned, and the circular waveguide section has a die Internal cross-sectional dimensions of the one directly adjacent to it Square waveguide not exceeding inner diameter on.

As can be seen from further subclaims, special training consists in that the two Square waveguide with the same internal cross-sectional dimensions and that the circular waveguide or Square waveguide section (e) a length of approx. Nλ / 4 (n = 1,3, 5, ....), where λ is the waveguide wavelength of the respective waveguide section.

The transition between the two by 45 ° against each other twisted square waveguides can e.g. for one Polarization conversion or used as a 3dB power divider become.

The different variants of a transition between two around Quadrant waveguides rotated by 45 ° are very good low reflection and they allow the individual Sections of the transition from the end faces by means of a milling machine can be processed. The milling is associated with a considerably lower effort than Electroplating or EDM processes.

Description of exemplary embodiments

Figur 1 a bzw. b Umwandlung einer vertikal bzw. einer horizontal polarisierten Grundwelle in zwei orthogonale Signalanteile,

Figur 2 einen Übergang zwischen zwei um 45° gegeneinander verdrehten Quadrathohlleitern, bestehend aus einem Rundhohlleiterabschnitt,

Figur 3 einen Übergang, bestehend aus 2 Rundhohlleiterabschnitten,

Figur 4 einen Übergang, bestehend aus zwei Quadrathohlleiterabschnitten mit abgerundeten Ecken,

Figur 5 einen Übergang mit zwei Quadrathohlleiterabschnitten mit abgerundeten Ecken und einem Rundhohlleiterabschnitt und

Figur 6 einen Übergang, bestehend aus einem Rundhohlleiterabschnitt und einem Quadrathohlleiterabschnitt mit abgerundeten Ecken.

The invention is explained in more detail below with the aid of several exemplary embodiments shown in the drawing. Show it:

FIG. 1 a or b conversion of a vertically or horizontally polarized fundamental wave into two orthogonal signal components,

FIG. 2 shows a transition between two square waveguides rotated relative to one another by 45 °, consisting of a round waveguide section,

FIG. 3 shows a transition consisting of 2 round waveguide sections,

FIG. 4 shows a transition consisting of two square waveguide sections with rounded corners,

Figure 5 shows a transition with two square waveguide sections with rounded corners and a round waveguide section and

Figure 6 shows a transition consisting of a round waveguide section and a square waveguide section with rounded corners.

Figures 1a and 1b illustrate that one in one Square waveguide 1 fed vertically polarized (Figure 1a) or horizontally polarized (Figure 1b) Fundamental wave through the transition to a square waveguide 2, compared to the square waveguide 1 around its longitudinal axis Is rotated 45 °, in two equally large orthogonal to each other divided polarized signal components of the basic wave type becomes. The arrows in FIGS. 1a and 1b indicate the Polarization directions of the signal components. Would one connect the second square waveguide 2 to a switch, which polarized the two orthogonally to each other the same large signal components from each other, you would have one 3dB power divider.

Would one in the second square waveguide 2 one of the two signal components acting phase shifting Insert medium that has a 90 ° phase difference between cause the two signal components, so one could Realize polarizer which is a linear polarization in converts a circular polarization.

In the figures 2 to 6 are some embodiments for the realization of a 45 ° transition between the two twisted against each other about their common longitudinal axis Square waveguides 1 and 2 shown. The transitions are designed so that they are as low reflection as possible and one require as little manufacturing effort as possible.

In Figures 2 to 6 there is one on the left side View from the end face of the first square waveguide 1 shown here in the transition. And on the right Side of Figures 2 to 6 is a longitudinal section A-A, B-B, C-C, D-D and E-E represented by the transition. The lines in Figures 2 to 6 give only the contours of Internal cross sections or longitudinal sections of the individual Waveguide sections again. The one in the individual Waveguide sections on the right side of FIGS. 2 to 6 drawn square or circle symbols indicate the Cross-sectional shape of the respective waveguide section.

The embodiment of a transition shown in Figure 2 between the first square waveguide 1 and him compared to second square waveguide 2 rotated by 45 ° consists of a circular waveguide section 3, the one Internal cross-sectional dimensions of both square waveguides 1 and 2 does not exceed the inner diameter. In the shown embodiment corresponds to the Inner diameter of the circular waveguide section 3 exactly Side length of the square waveguide 1 and 2.

When executing the transition in Figure 3 is to the Round waveguide section 3 yet another Round waveguide section 4 with a smaller diameter connected as the waveguide section 3. One can also more than just two such transformation stages Switch in series to make the transition less reflective shape.

The transition shown in Figure 4 between the first Square waveguide 1 and the second square waveguide 2 consists of two in a row in the direction of the longitudinal axis arranged square waveguide sections 5 and 6 with rounded corners. The first square waveguide 1 directly adjacent square waveguide section 5 each of the two square waveguide sections 5 and 6 are the same aligned like the one directly adjacent to it Square waveguide 1 and 2. That is, the Square waveguide section 5 is with respect to the first Square waveguide 1 50 rotated that its side walls parallel to the side walls of the square waveguide 1 are aligned, and the square waveguide section 6 about the longitudinal axis common to all waveguide sections rotated that its side walls are parallel to the side walls of the square waveguide 2 are aligned. As the view can be seen in the left part of Figure 4, the Internal cross section of the square waveguide section 5 is not larger than the inner cross section of the neighboring one Square waveguide 1. Likewise, the inner cross section of the Square waveguide section 6 not larger than that Internal cross section of the adjacent square waveguide 2. It can also be between the two Square waveguide sections 5, 6 with rounded corners or several more square waveguide sections with rounded corners are inserted, the inner cross-sections must not be larger than the one on each side adjacent waveguide section.

The transition in FIG. 5 differs from that in FIG. 4 in that a round waveguide section 7 is also inserted between the two square waveguide sections 5 and 6.
With this additional transformation level, the reflection properties of the transition can be further improved. Instead of the round waveguide section, a square waveguide section with rounded corners can also be used, the inner cross section of which is smaller than that of the two adjacent waveguide sections.

The transition shown in Figure 6 consists of a Round waveguide section 8 and a square waveguide 9 together. The one following the square waveguide 1 Round waveguide section has a diameter that is not goes beyond the side length of the square waveguide 1. in the special case is the diameter of the Round waveguide section 8 equal to the side length of the Square waveguide 1. On the round waveguide section 8 includes a square waveguide section 9 rounded corners. This square waveguide section 9 is rotated about the longitudinal axis so that its side walls parallel to the side walls of the one directly adjacent to it Square waveguide 2 are aligned. Moreover exceed the internal cross-sectional dimensions of the Square waveguide section 9 not the Inner cross-sectional dimensions of the square waveguide 2.

The fact that in all previously described Embodiments of the transition between the two Square waveguide 1 and 2 inserted waveguide sections with their internal cross-sectional dimensions not the Internal cross-sectional dimensions of the neighboring ones Crossing square waveguide 1, 2 is a processing of the waveguide sections from the end faces of the Square waveguide 1 and 2 ago by means of a milling machine possible. The round or square cross-sectional shapes with rounded corners of the Simply produce waveguide sections.

In the illustrated embodiments, the Inner cross sections of the square waveguide 1 and 2 of the same size. But they can also differ from each other. So that the individual waveguide sections of the transition like Transformation stages are effective if they are approx. nλ / 4 (n = 1, 3, 5, ....), where λ is the Waveguide wavelength of the respective waveguide section is.

Claims (9)

Transition between two around a common longitudinal axis 45 ° twisted square waveguides, thereby characterized in that between the two square waveguides (1, 2) a circular waveguide section (3) is present, one the inner cross-sectional dimensions of both square waveguides (1, 2) has an internal diameter not exceeding. Transition according to claim 1, characterized in that towards the longitudinal axis Round waveguide section (3) at least one other Round waveguide section (4) with another Connects inner diameter, which also the Internal cross-sectional dimensions of both square waveguides (1, 2) does not exceed. Transition between two around a common longitudinal axis 45 ° twisted square waveguides, thereby characterized in that between the two square waveguides (1, 2) two lined up in the direction of the longitudinal axis Square waveguide sections (5, 6) with rounded corners are present that each of the two Square waveguide sections (5, 6) about the longitudinal axis so is rotated that its side walls parallel to the Side walls of the square waveguide directly adjacent to it (1, 2) are aligned and that the Internal cross-sectional dimensions each Square waveguide section (5, 6) Internal cross-sectional dimensions of the one directly adjacent to it Do not exceed the square waveguide (1, 2). Transition according to claim 3, characterized in that between the two square waveguide sections (5, 6) at least one circular waveguide section (7) is inserted, whose inside diameter is the inside cross section dimensions of the two square waveguide sections (5, 6) not exceeds. Transition between two around a common longitudinal axis 45 ° twisted square waveguides, thereby characterized in that between the two square waveguides (1, 2) in the direction of the longitudinal axis Round waveguide section (8) and a Square waveguide section (9) with rounded corners are strung together that the square waveguide section (9) is rotated about the longitudinal axis so that its side walls parallel to the side walls of the one directly adjacent to it Square waveguide (2) are aligned, and that the Round waveguide section (8) a Internal cross-sectional dimensions of the one directly adjacent to it Square waveguide (1) not exceeding Has inner diameter. Transition according to one of claims 1 to 5, characterized characterized in that the two square waveguides (1, 2) have the same internal cross-sectional dimensions. Transition according to one of claims 1 to 5, characterized characterized in that the round waveguide or Square waveguide section (s) (3, 4, 5, 6, 7, 8, 9) one Has a length of approx. Nλ / 4 (n = 1, 3, 5, ...), where λ is the Waveguide wavelength of the respective waveguide section is. Transition according to one of claims 1 to 7, characterized characterized that he is for a polarization converter is used. Transition according to one of claims 1 to 7, characterized characterized that he is for a 3dB power divider is used.

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