The present invention concerns a device for coupling a radio frequency signal propagating in a metallic conductor into a waveguide or from a waveguide into a metallic conductor.
Conventional coupling devices of this type comprise a waveguide section in which a guided wave is capable of propagating in at least one waveguide mode and which has a slit in one of its walls, through which the field of the waveguide mode emerges and is capable of exciting an oscillation in an antenna section arranged outside the waveguide section, bridging the slit.
Only a part of the radio frequency energy emerging through the slit is actually utilised for exciting the oscillation in the antenna section; the remainder is radiated into the free space lying above the slit. This is undesirable, not only because the energy is thereby radiated unused, but because it may have an interfering influence on equipment components situated in the free space.
If, for instance, a coupling device of this type is used in a group antenna in order, via slits in the walls of a waveguide and antenna sections arranged crossing it, to feed individual antenna elements of the group antenna, then the interference radiation emerging from the slits may sensitively impair the field pattern of the group antenna.
In W. Keusgen and B. Rembold, “broadband Planar Subarray for Microwave WLAN Applications”, MIOP, Stuttgart, 2001, it is proposed to circumvent this problem in that the interference radiation is coupled into a radiator element which actively contributes to the function of the group antenna. This solution involves a significant calculation effort, however, and is not generally applicable.
In F. J. Villegas, D. I. Stones, H. A. Hung: “A Novel Waveguide-to-Microstrip Transition for Millimeter Wave Applications”, IEEE Trans. on Microwave Theory and Techniques, vol. 47, No. 1, January 1999, it is proposed that the interference radiation be suppressed with the aid of cover caps placed over the respective slits to prevent emergence of the interference radiation. However, this solution is complex in the implementation, since for every slit such a cover with fed-through antenna section is required.
It is an aim of the present invention to provide a waveguide coupling device of the aforementioned type in which the emergence of interference radiation is effectively suppressed in simple manner and which may be manufactured with little effort.
This aim is fulfilled by providing, in the side wall which has the first slit, a second slit which is so arranged that the two slits lie on opposite sides of a nodal line of a field component of the waveguide mode that is oriented parallel to the slotted wall.
The invention is preferably applied to a waveguide of rectangular cross-section and particularly to its principal mode, known as the magnetic fundamental wave or the H10 wave. Based on the explanations given here, however, a person skilled in the art will be able to apply the invention also to other waveguide cross-sections and waveguide modes.
If a coordinate system is established whereby the X-axis is perpendicular to a narrow side wall and the Y-axis is perpendicular to a broad side wall of the waveguide section and the Z-axis extends in the longitudinal direction of the waveguide section, the H10 wave has field components Hx and Hz parallel to a broad side wall of the waveguide. Of these components, the component Hz has a nodal plane, which extends in the longitudinal direction of the waveguide section and intersects its two broad side walls centrally. The Hz component has opposite signs on the different sides of the nodal plane. Thus the fields emerging from the two slits and originating from the Hz component oscillate with opposing phase and tend to cancel each other out in the radiation zone. The Ey component of the H10 wave excites, in the side walls of the waveguide section, cross-currents which flow in opposing directions on either side of the same nodal plane and evoke opposite-oriented electric fields in the X-direction at the two slits. These also tend to cancel each other out in the radiation zone.
This cancellation is all the more complete, the more symmetrical is the arrangement of the two slits in relation to the nodal plane. If the locus of one slit is the reflection of the other with respect to the nodal plane, then their Ex components compensate each other completely in the radiation zone on the nodal plane, provided the symmetry is not broken by the antenna section crossing the first slit, and are severely reduced laterally by this compared with the field of a waveguide section having a single slit.
With an inversion symmetry arrangement of the slits relative to a point in the nodal plane, that is to say, the locus of one slit is the inverted reflection of the other with respect to the nodal plane, sufficient compensation may also be achieved, provided the extent of the slits in the Z-direction is significantly smaller than the wavelength of the waveguide mode and thus phase differences between the fields at inversion symmetrical points of the two slits can be ignored.
The antenna section is in general linked at one end to a conductor for conducting away the coupled-in RF signal and free at its other end. This free end may preferably be placed at a distance of λs/4 from the slit, either fixed or adjustable, where λs is the wavelength of the signal induced in the antenna section. This achieves the result that a portion of the coupled-in signal propagating in the antenna section from the slit directly in the direction of the connecting conductor and a portion initially reflected at the free end are constructively combined, so that a strong coupling is achieved.
In order to avoid break of symmetry through an intersecting antenna section, a second antenna section may advantageously be arranged bridging the second slit. This antenna section may be employed for feeding a different RF component from that fed by the first antenna section, or for feeding the same RF component.
According to a preferred embodiment, in the latter case, two antenna sections are linked at one point parallel to a connecting conductor, i.e. they each have one end linked to the connecting conductor and one free end.
The antenna sections may be so arranged that they cross the slits assigned to them in respective opposing directions, i.e. their free ends either both lie between the slits or both beyond the slits. In this case it is preferred that the antenna sections should have a total length L between (n−⅜)λs and (n+⅜)λs, where n is an integer and λs is the wavelength of the oscillation induced in the antenna sections by the guided wave. If L is exactly equal to nλs, then the oscillations coupled at the two slits in the antenna sections interfere exactly cophasally and optimum coupling is achieved. Values deviating from nλs may be used if a weaker coupling is desired.
If, on the other hand, the antenna sections cross their slits in the same direction, i.e. if the free end of one antenna section lies between the slits and that of the other lies beyond the slits, then the oscillations induced at the slits interfere cophasally at a total length L of (n+½)λs, by reason of which a total length L of between (n+⅛)λs and (n+⅞)λs is preferred.
Another possibility is to link the two antenna sections in series; in this case, for a cophasal superposition of the oscillations induced at the two slits, a spacing between the slits measured along the antenna sections of approximately nλs if the antenna sections cross the slits in opposing directions, or of approximately (n+½)λs is required if the antenna sections cross the slits in the same direction.
Preferably, the crossing points of the antenna sections with the slits lie on a line perpendicular to the longitudinal direction of the waveguide section or to the nodal plane.
It is thereby ensured that the two antenna sections are exposed to cophasal exciting fields emerging from the slits, independently of the exact position in which the antenna sections are arranged in relation to the waveguide section. It is particularly suitable if the antenna sections lie, at least in the region of the crossing points, on a common line, so that the phase coincidence of the fields to which the two antenna sections are exposed is maintained even on transverse displacement of the antenna sections.
According to a first preferred embodiment, the two slits are parallel to each other and to the nodal plane, so that the coupling strength does not depend on the position of the antenna sections in the propagation direction of the guided wave (the Z-direction), but is determined exclusively by the position of the antenna sections transverse to the nodal plane, i.e. by the spacing of their crossing points from the free ends.
According to a second preferred embodiment, the slits run parallel and inclined to the nodal plane. The degree of deviation from parallelism influences the strength of the Hz field emerging from the slits and coupling into the antenna sections and thus the coupling constant of the coupling device. In particular if the slits are arranged on a rotatable wall section of the waveguide section, by rotation of this wall section, the coupling constant may be adjusted as required.
According to a third preferred embodiment, the slits have a spacing varying along the nodal plane and the antenna sections are positionable in different positions along the nodal plane. In this case, the coupling coefficient may be set by suitable positioning of the antenna sections along the nodal plane. The nearer the slits lie to the nodal plane, the smaller is the field component parallel to the wall in the waveguide behind the slits and the smaller are the wall currents induced at the site of the slits, and the smaller therefore is the emerging field to which the antenna sections are exposed.
In the first and third embodiments, it may be provided that, when manufacturing the coupling device, the antenna sections are firmly placed at a site, whereby the antenna sections may be fixed at several positions on the waveguide section and the position in an individual case is selected on the basis of a desired coupling coefficient. Alternatively, the possibility exists of providing a device for adjusting the antenna sections relative to the slits, in order also to be able to adapt the coupling coefficients of the finished coupling device to requirements at any time.
Further features and advantages of the invention are given in the following description of examples by reference to the attached drawings, in which
The coupling device shown in
A first slit 4 extends in the upper broad side wall 2 in the direction of the z axis. A second slit 5 is arranged relative to the nodal plane x=a/2 as a mirror image of the first slit 4. Fields emerging from the two slits 4, 5 are composed of contributions from the non-vanishing field components passing through the slit, and electric fields in the x-direction resulting from the fact that the slits 4, 5 block the path of cross-currents flowing in the waveguide wall and evoked by the waveguide mode. These cross-currents, illustrated schematically in
On the upper broad side wall 2 is arranged a dielectric substrate 6, which bears a first strip line 7 bridging the first slit 4. The strip line 7 serves as an antenna section in which an electromagnetic oscillation is induced by the electric field evoked by the cross-currents. This oscillation may be used to feed an antenna element of a group antenna or another RF component.
A second strip line 9 may be arranged in mirror image fashion to the strip line 7 over the second slit 5. Its function is the same as that of the first strip line; it may be used to feed the same RF component as the first strip line 7, or a second RF component.
In the second embodiment of the coupling device according to the invention shown in
In the embodiment according to
In the variation shown in
Variable coupling coefficients are also realisable with the design according to
By suitable selection of the position of the substrate 6, it is thus possible to set the strength of the coupling between the waveguide section 1 and the strip lines 7′, 9′. This significantly simplifies the manufacture of coupling devices with different coupling strengths, since it is not necessary to set the position of the slits 4, 5 according to a desired coupling strength and to manufacture a plurality of waveguide sections with differing slit spacings, but the waveguide sections 1 may be manufactured in large quantities with a fixed position of the slits and the desired coupling strength may be subsequently selected by suitable positioning of the substrate 6.
Naturally, the spacings of the crossing points 12 from the free ends 13 and the spacings of the crossing points 12 from each other do not have to be λs/4 and λs/2, respectively, at the same time. Indeed, strong coupling may be achieved with such spacings, but only within a very narrow frequency range. If, for at least one of these spacings, a not exactly optimal value is chosen, but rather one lying close to it, then at somewhat reduced coupling strength, the bandwidth of the coupling device may be significantly increased.
A variation of the principle in
The embodiment shown in
A particularly simple embodiment with strip lines 7**, 9** crossing the slits 4, 5 of the waveguide section 1 in the same direction is shown in
A further embodiment of the coupling device is shown in
The length of the slits in the Z-direction is chosen such that the phase difference of the fields at opposing ends of the slits 4′, 5′ is not more than 15°. The angle α influences the strength of the Hz component of the waveguide mode emerging through the slits 4′, 5′ and thus the strength of the magnetically induced current in the strip lines 7′, 9′. At an angle α=0, this is a maximum; at a value of 90°, it would vanish.
A further development of this embodiment is shown in
Naturally, with the embodiments in
A plurality of the aforementioned coupling devices may be arranged along a single waveguide. The spacing between the individual coupling devices should then be half the wavelength λH of the wave in the waveguide, so that the residual scattering fields of the individual coupling devices cancel each other out in the radiation zone.
Number | Date | Country | Kind |
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102 02 824 | Jan 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB03/00610 | 1/24/2003 | WO | 00 | 3/7/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/063297 | 7/31/2003 | WO | A |
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Number | Date | Country | |
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20050163456 A1 | Jul 2005 | US |