JPH02312302A - Waveguide circuit - Google Patents

Abstract

PURPOSE:To synthesize power of two orthogonal polarized electromagnetic waves in one plane by one rectangular waveguide by giving the difference of a half wavelength in the waveguide between distances from respective L-type bends to a T-type branch. CONSTITUTION:L-type bends 1 which convert the propagation direction of an input electromagnetic wave to opposite directions in the same plane are provided in the vicinity of a pair of electromagnetic wave input terminals A and B, and a T-type branch 2 is provided to synthesize a pair of electromagnetic wave inputs propagated in opposite directions in this plane into electromagnetic waves in propagation directions orthogonal to each other in the same plane with respect to power. Distances from respective L-type bends 1 to the T-type branch 2 are different from each other by lambdag/2 where lambdag is the wavelength in the waveguide. Thus, power of two orthogonal polarized electromagnetic waves are synthesized by one waveguide circuit.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a waveguide circuit that combines power of electromagnetic waves of two orthogonal polarizations, and for example, a waveguide circuit for receiving electromagnetic waves of two orthogonal polarizations. This can be used as a waveguide feeding circuit for planar antennas.

[Prior Art] Conventionally, for example, the feeding circuit of a planar array antenna that receives electromagnetic waves of two orthogonal polarizations has been constructed of strip lines, and the electromagnetic waves of each (layer liquid) have been synthesized using the strip lines. However, the strip line has a large transmission loss, and this loss causes a problem in that the receiving performance of the planar array antenna deteriorates.

[Problems to be Solved by the Invention] Therefore, it is conceivable to configure the feeding circuit of the planar array antenna with a waveguide circuit. In this case, it is necessary to provide a feeding circuit using two series of waveguides corresponding to each polarized electromagnetic wave output from each antenna element in the planar array antenna. For this reason, the configuration of the feeder circuit becomes three-dimensionally very complex, leading to an increase in product cost and the problem of impairing the planarity of the planar array antenna.

The present invention has been made in view of these points, and its purpose is to provide a waveguide that can achieve power synthesis of two orthogonally polarized electromagnetic waves on the same plane using one series of waveguides. The purpose is to provide wave tube circuits.

[Means for Solving the Problems] In order to solve the above problems, in the waveguide circuit according to the present invention, as shown in FIG. A pair of electromagnetic wave input ends A
, B are provided with L-shaped vents 1 for converting the propagation direction of the input magnetic waves into directions opposite to each other within the same plane, and the pair of electromagnetic wave inputs propagated in opposite directions within the plane are It is equipped with a T-shaped branch 2 that combines power with electromagnetic waves in propagation directions perpendicular to each other in a plane, and the distance from each bent bend 1 to the T-shaped branch 2 is λg/2, where λg is the internal wavelength of the waveguide. It is characterized by the following differences:

[Function] In the present invention, as described above, since the distances from the pair of L-shaped vents 1 to the T-shaped branch 2 differ by λg/2, two orthogonal polarized waves are propagated in the waveguide. Power synthesis of electromagnetic waves is performed for each polarized wave, and power synthesis of two orthogonal polarized electromagnetic waves can be achieved by one waveguide circuit.

[Embodiment] FIG. 1 is a perspective view of a waveguide circuit according to an embodiment of the present invention. The fundamental mode of the rectangular waveguide used in this waveguide circuit is TE. mode. For convenience of explanation, in FIG. 1, the polarized waves indicated by solid arrows are TE. Mode: The polarized wave indicated by the dashed arrow is defined as TE mode.

For example, as shown in FIG. 4, this waveguide circuit is used as a parallel feeding circuit for a planar array antenna 3 capable of receiving two polarized waves, horizontally polarized waves and vertically polarized waves. Each antenna element 4 in the planar array antenna 3 shown in FIG. 4 is a waveguide aperture antenna capable of receiving horizontally polarized waves shown in solid lines and vertically polarized waves shown in broken lines. Therefore, in the waveguide circuit shown in FIG. 1, the electromagnetic wave input ends A , B ,
Polarized waves indicated by solid arrows and polarized waves indicated by broken arrows are input to C and D.

In FIG. 1, the L-shaped vents 1 provided at the electromagnetic wave input ends A and B are TE shown by solid arrows. For the mode electromagnetic waves, as shown in FIG. 3(a), it acts as an eight-sided (plane parallel to the magnetic field) wedge-shaped bent (H corner).

Therefore, the transmission direction of the electromagnetic waves is changed by the L-shaped vent, and the electromagnetic waves vibrate in the same phase in the B-plane and the B-plane as shown in the figure. In this way, the TE whose propagation direction is changed to the direction along the back surface of the planar array antenna by the L-shaped vent 1,
. In the case where the power of the electromagnetic waves of the mode is combined in the direction along the back surface of the antenna using the T-shaped branch 2, as shown in Fig. 2 (b
) will be used. Here, when using the E-plane branch, the phases of the two electromagnetic waves to be combined (■, ■ in the figure) must be reversed at the T-shaped branch 2. Therefore, the point p constituting the first T-shaped branch 2 shown in FIG. 1 is a point shifted by λg/4 from a point equidistant from the A' plane and the B' plane. Therefore, A'-
Since there is a difference of λg/2 between the distance between P and the distance between B' and P, the electromagnetic waves of the TE mode, which were in the same phase on the A' plane and the B' plane, are out of phase at the P point. Then, Figure 2 (b
) are synthesized into one electromagnetic wave (■ in the figure) by the E-plane branch.

On the other hand, for electromagnetic waves in the TE mode shown by the dashed arrow, the L-shaped vents provided at the electromagnetic wave input terminals A and B in Fig. 1 have six sides as shown in Fig. 3(b). (plane parallel to the i-field) acts as a rectangular bend (E corner). Therefore, due to the L-bend, the electromagnetic wave changes its transmission direction,
As shown in the figure, the A' and B' planes vibrate in opposite phases. In this way, when the electromagnetic waves of the TE mode whose propagation direction is converted to the direction along the back surface of the planar array antenna by the L-shaped bend 1 are combined in power in the direction along the back surface of the antenna by the T-shaped branch 2, In this case, an H-plane branch as shown in FIG. 2(a) is used. Here, H
When using surface branching, two electromagnetic waves to be synthesized (■
, ■) must be in phase at the T-type branch. As mentioned above, the point P forming the first T-shaped branch 2 shown in FIG.

The point is shifted by λg/4 from a point equidistant from the plane and B' plane. For this reason, there is a difference of λg/2 between the distance between A'-P and the distance between B'-P, so the electromagnetic wave of the TE mode, which was in opposite phase between the A° and B' planes, becomes At point P, the waves become in phase and are combined into one electromagnetic wave (■ in the figure) by the H-plane branch shown in FIG. 2(a).

Furthermore, as shown in FIG. 1, the TE, mode and T E
, mode electromagnetic waves are also combined in power at point Q, and at point R on the opposite side (inside) of points P and Q, the second
A T-shaped branch 5 is constructed. At this time, T E shown by the solid line
+. The electromagnetic waves in the mode have opposite phases at points P and Q, and the electromagnetic waves in the TE mode shown by the broken line have the same phase at points P and Q.

Therefore, if a T-shaped branch 5 is constructed at a point R that is equidistant from points P and Q, then TE. For electromagnetic waves in mode, it is branched as E-plane, and for electromagnetic waves in mode TE, I
(Acts as a plane branch, and power is combined for both modes of electromagnetic waves at the same time. As a result, for a four-element planar array antenna as shown in Figure 4, a feeding circuit for electromagnetic waves of two orthogonal polarizations is created. It can be configured with one waveguide circuit.

FIG. 5 is a schematic configuration diagram of another embodiment of the present invention. In this embodiment, two sets of waveguide circuits as shown in FIG. A third T-shaped branch 6 is provided at a point S (1 m (inside)) opposite to the second T-shaped branch.The point S where this third T-shaped branch 6 is provided is It is located equidistant from the second T-shaped branch 5 in the circuit.Therefore, at point S, the electromagnetic waves in the TElo mode are out of phase, the electromagnetic waves in the TE mode are in phase, and the third
The T-shaped branch 6 acts as an E-plane branch and an H-plane branch, respectively, and can combine the power of two modes of electromagnetic waves at the same time. As a result, for an 8-element planar array antenna, a feeding circuit for electromagnetic waves of two orthogonal polarizations can be configured with one waveguide circuit.

Moreover, two sets of waveguide circuits as shown in FIG. If we set 16
A waveguide feeding circuit for a planar array antenna of elements can be constructed. Hereinafter, a waveguide feeding circuit for a planar array antenna of 2n elements (n≧5) can be constructed in the same manner. In this case, the number of T-type branches required is (2n-1).

[Effects of the Invention] The present invention is a power combining circuit using a rectangular waveguide, in which the propagation directions of input electromagnetic waves are made to be opposite directions within the same plane by L-shaped bends provided near a pair of electromagnetic wave input ends, The power of this pair of input electromagnetic waves is combined in the orthogonal propagation directions within the plane using a T-shaped branch, and the distances from each bent bend to the T-shaped branch are made to differ by half a wavelength in the waveguide, so that they are orthogonal. This has the effect that the power of two compensating electromagnetic waves can be combined on the same plane using one system of rectangular waveguides.

Furthermore, by connecting similar waveguide circuits in multiple stages using T-shaped branches, it is possible to configure a 2n-branched power combining circuit.

[Brief explanation of drawings]

FIG. 1 is a perspective view of one embodiment of the present invention, and FIG. 2(a). (b) is an explanatory diagram of the operation of the T-type branch used in the above, and the third [J
(g) and (b) are explanatory diagrams of the operation of the L-shaped bend used in the above, FIG. 4 is a perspective view of a planar array antenna fed by the above embodiment, and FIG. It is a schematic block diagram. 1 is an L-shaped bend, 2 is a T-shaped branch, and A and B are electromagnetic wave input ends.

Claims (3)

[Claims] (1) A power combining circuit composed of a rectangular waveguide, each equipped with an L-shaped bend near a pair of electromagnetic wave input ends for converting the propagation direction of the input electromagnetic wave into directions facing each other within the same plane, A T-shaped branch for power-synthesizing the pair of electromagnetic wave inputs propagating in opposite directions in the plane into electromagnetic waves in orthogonal propagation directions in the plane, and from each L-shaped bend to the T-shaped branch. A waveguide circuit characterized in that the distances differ by half a wavelength within the waveguide. (2) A pair of waveguide circuits according to claim 1 are provided, and each waveguide circuit is configured such that the electromagnetic waves output from the T-shaped branch in each waveguide circuit are propagated in opposite directions within the plane. and a second T-shaped branch for power-synthesizing the electromagnetic waves output from each waveguide circuit in propagation directions perpendicular to each other within the plane, and the second T-shaped branch and each waveguide circuit A waveguide circuit characterized by being arranged at an equal distance from a T-shaped branch. (3) 2^n waveguide circuits (n is an integer of 1 or more) according to claim 2 are provided, and the electromagnetic waves output from the 2^n waveguide circuits are power-combined within the plane. T-shaped branch (2
^n-1) waveguide circuit.