EP0330540A1 - Waveguide power divider - Google Patents

Abstract

Waveguide power divider for a microwave energy transmission circuit operating at high power in the rectangular TE10 mode. …<??>It consists of the juxtaposition:… - of a rectangular entrance waveguide (1) operating in its fundamental mode and receiving, via one of its ends (2), the power to be divided and whose other end (3) is closed;… - of a circular waveguide (4) propagating the TM01 mode and connected to the rectangular guide (1) by a lateral opening (10) in such a way that the axes of the two guides are perpendicular;… - of a group of n exit waveguides (15) placed at the exit of the circular waveguide (4) and distributed in a ring ahead of its free end, operating in the TE10 mode and each transmitting a fraction of the power introduced at the entrance. …<??>Application to microwave energy transmission circuits. …<IMAGE>…

Description

The present invention relates to a power divider in waveguide, for microwave power transmission circuit operating at high power. The technique of millimeter and centimeter waves of great power is currently developing thanks to generators and amplifiers such as gyrotrons.

There are already waveguide power dividers. Two types have been widely developed, those in the form of Y and those in the form of T. These dividers consist of an input waveguide which gradually deforms in order to obtain two output waveguides. The set has the form of the capital letter T or the capital letter Y.

These power dividers allow the power introduced into the input guide to be divided into two equal or unequal parts. It depends on the dimensions of the section of the waveguides making up the three branches of the T or Y. In the case where the three branches have the same section, the power transmitted in the two output waveguides will be half of the power injected at the input. These power dividers are also called 3dB couplers.

If you want to divide the power input, in addition to two equal parts, you must assemble several T or Y dividers in series. This type of assembly does not, however, allow a division by a odd number, nor by an even number other than a power of two. In addition, power dividers of this type are generally quite large, especially if one is forced to assemble several, in series, to obtain a division by a power of two.

The object of the present invention is to remedy these drawbacks by presenting a power divider as a waveguide which is not very bulky and making it possible to obtain in each of the n output waveguides a fraction of the power injected into the input waveguide, n being an integer greater than or equal to two. This number n is however limited to the quantity of output waveguides that it is possible to juxtapose mechanically.

This power divider allows the passage of high powers. It is produced by the juxtaposition of several waveguide sections. It has a particularly compact shape even if the number n of output waveguides is quite large. It operates in the TE₁₀ rectangular mode, which is the fundamental mode of the rectangular section waveguides. This mode is frequently used in microwave energy transmission circuits.

The present invention provides:
a waveguide power divider for a microwave power transmission circuit, operating at high power, in the rectangular TE₁₀ mode, comprising:
- a rectangular input waveguide operating in its fundamental mode, receiving at one of its ends the power to be divided and having another closed end;
a circular waveguide, propagating the TM₀₁ mode, having a first end connected to the input rectangular waveguide by a lateral opening placed in the long side of the rectangular waveguide, near its closed end, of such that the axes of the two guides are perpendicular;
divider characterized in that it further comprises a group of n output waveguides operating in the TE₁₀ rectangular mode, distributed in a ring in front of a second end of the circular waveguide so that at least one of their long sides are cut substantially perpendicularly by a radius of the cross section of the circular guide and so that they each transmit in TE₁₀ mode a fraction of the power introduced into the rectangular input waveguide.

• - la figure 1 : une coupe longitudinale d'un diviseur de puissance de type Y selon l'art antérieur ;
• - la figure 2 : une coupe longitudinale d'un diviseur de puissance selon l'invention ;
• - la figure 3 : une coupe transversale selon l'axe AA' de ce diviseur de puissance ;
• - les figures 4a à 4f diverses sections possibles pour les n guides d'ondes de sortie.

Other characteristics and advantages of the invention will appear on reading the following description, illustrated by the appended figures which represent:

• - Figure 1: a longitudinal section of a type Y power divider according to the prior art;
• - Figure 2: a longitudinal section of a power divider according to the invention;
• - Figure 3: a cross section along the axis AA 'of this power divider;
• - Figures 4a to 4f various possible sections for the n output waveguides.

In the figures, the same references designate the same elements.

The waveguide power divider shown in FIG. 1 is of the Y type.

The input waveguide 20 is for example a rectangular waveguide. It propagates an electromagnetic wave in the TE₁₀ rectangular mode.

This waveguide 20 is gradually deformed in order to obtain two output waveguides 21, 22.

In our example, the two output waveguides 21, 22 have the same section. They also have the same section as the input waveguide 20. The power transmitted in each of the output waveguides 21, 22 will be half the power introduced into the input waveguide 20. This assembly is a divider of power by two. By adding to the output of each of the two waveguides 21, 22 a power divider of type Y as described above, one would obtain a power divider by four. With this kind of assembly the power is always divided by a power of two.

FIG. 2 represents, in longitudinal section, a power divider according to the invention. This power divider is made up of the juxtaposition of several waveguide sections.

The entry is made by a waveguide 1 of rectangular section, operating in its fundamental mode. This rectangular waveguide 1 input is excited by a source of electromagnetic waves 12 placed at its upper end 2. Its lower end 3 is closed. A first end of a waveguide of circular section 4 is connected to the rectangular waveguide 1 of entry by a lateral opening 10 placed in the long side of the rectangular waveguide 1 of entry near its end closed 3.

The axes of the two waveguides are perpendicular.

The waveguide 4 propagates the TM₀₁ mode because the distribution of the magnetic field in the rectangular waveguide 1 input at the level of the opening 10 corresponds to that of the TM₀₁ mode in the waveguide 4 of circular section . The opening 10 in the rectangular waveguide 1 input is large, which allows operation at high powers.

This structure makes it possible to transform the rectangular TE₁₀ mode into the circular TM₀₁ mode.

The power injected into the rectangular waveguide 1 input is transmitted into the circular waveguide 4.

A group of n output waveguides 15 is disposed at the other end 9 of the circular waveguide 4. Their longitudinal axes are parallel to that of the circular guide 4 but not coincident with it.

These n output waveguides 15 are distributed in a ring at the periphery of the circular waveguide 4. Each of these n output waveguides 15 has a rectangular section or of similar shape: trapezoidal, elliptical, with angles rounded, etc ...

They are placed so that their long sides 13 are cut substantially perpendicularly by a radius of the cross section of the circular waveguide 4.

They are chosen singlemode, they all have the same length and are supplied in phase.

The number n of output waveguide 15 is arbitrary but however greater than or equal to two.

In our example, there are shown four output waveguides 15, which have the same rectangular section.

The power injected into the rectangular input waveguide 1 being P, the power transmitted in each of the n output waveguides 15 will be p = P / n, if the n output waveguides 15 have the same section.

In the example chosen, each output waveguide 15 will transmit a quarter of the power injected into the rectangular input waveguide 1.

FIG. 3 represents, in section along the axis AA ′, the four output waveguides 15. The distribution of the electric field is indicated inside each of them.

The distribution of the electric field, in the circular waveguide 4, is also shown.

In each of the output waveguides 15 propagates the rectangular TE₁₀ mode. Indeed, the distribution of the electric field in the circular waveguide 4 propagating the TM₀₁ mode is along the radii of its cross section. In the n output waveguides 15, this distribution corresponds to that of the rectangular TE₁₀ mode.

In order to obtain optimum operation, it may be necessary to make a compromise on the one hand, between the dimensions of the n output waveguides 15 and those of the circular waveguide 4, and on the other hand the distance separating each axis of the n waveguides 15 from the axis of the circular waveguide 4.

This is why the diameter of the circular waveguide 4, at the junction with the n output waveguides 15, can be different from the optimal diameter of the circular waveguide 4 used for the first transition, this is ie for the transformation of the TE₁₀ rectangular mode into circular TM en mode.

In this case a diameter transition must be incorporated between the circular waveguide 4 and the n output waveguides 15. This transition can be done by single jump as shown in 6 in FIG. 2, by successive jumps or gradually. In the latter case, a progressive fitting will be introduced.

FIGS. 4a to 4f represent various possible shapes of the cross section of the n output waveguides 15.

These sections can be in the sector of the crown (fig. 4a) trapezoidal (fig. 4b), trapezoidal with rounded corners (fig. 4c), elliptical (fig. 4d), rectangular with four rounded sides (fig. 4e), trapezoidal with four curved sides (fig. 4f). Still other forms can be used.

The sections shown in FIGS. 4a to 4c and 4f make it possible to place a maximum of output waveguides 15 at the periphery of the circular waveguide 4 because they are slightly trapezoidal.

This allows the power to be divided by a fairly large number.

The sections shown in Figures 4d to 4f will allow the passage of a higher power because of their curved sides.

The elements bearing the mark 7 in FIG. 1 are fixing flanges which make it possible to connect one waveguide to another.

Claims (4)

1. Power divider in waveguide for microwave power transmission circuit operating at high power, in the rectangular TE₁₀ mode, comprising:
- a rectangular waveguide (1) input operating in its fundamental mode, receiving by one of its ends (2) the power to be divided and having another end (3) closed
- a circular waveguide (4), propagating the TM₀₁ mode, having a first end connected to the input rectangular waveguide by a lateral opening (10) placed in the long side of the rectangular waveguide (1 ) near its closed end (3), so that the axes of the two waveguides are perpendicular;
divider characterized in that it further comprises a group of n output waveguides (15) operating in the TE₁₀ rectangular mode, distributed in a crown in front of a second end (9) of the circular waveguide (4) of so that at least one of their long sides (13) is cut substantially perpendicularly by a radius of the cross section of the circular guide (4) and so that they each transmit in TE₁₀ mode a fraction of the power introduced into the input rectangular waveguide (1). 2. Power divider in waveguide for microwave energy transmission circuit according to claim 1, characterized in that the cross section of the n output waveguides (15) is rectangular or of neighboring shape. 3. Power divider in waveguide for microwave energy transmission circuit according to one of claims 1 or 2, characterized in that the n output waveguides (15) are identical. 4. Power divider in waveguide for circuit transmission of microwave energy according to claim 3, characterized in that the n output waveguides (15) transmit one nth of the power introduced into the rectangular waveguide (1) input.

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