Not Applicable
Not Applicable
This disclosure relates generally to the field of transducers for electromagnetic signals, particularly RF and microwave signals. More specifically, this disclosure relates to waveguide-type orthomode transducers (OMTs).
Waveguide Orthomode Transducers (OMTs) are widely used in microwave systems, particularly in radars and radiometry, where polarization diversity is required. In wireless communications, OMTs are used to receive signals having a first polarization, and to transmit signals having a second, orthogonal polarization in a single antenna. A typical OMT is a three-port device that separates and/or combines the two orthogonally-polarized signals.
The main qualities sought in an OMT are high polarization purity, high port-to-port isolation, wide frequency coverage, and compact dimensions. Compactness is an important feature, since OMTs are commonly configured as part of reflector antenna feeds. In center-fed reflector antennas, the small size of the feed is important for minimizing central blockage and associated beam distortion of the antenna. Some existing OMTs (U.S. Pat. No. 6,842,085, for example) may be relatively compact, but they are typically operable over a relatively narrow frequency range, because, due to features inherent in their design, they tend to excite higher order waveguide modes that can reduce port-to-port isolation, increase cross-polarization, and increase voltage standing wave ratio. For example, many relatively compact OMTs, such as that disclosed in the aforementioned U.S. Pat. No. 6,842,085, have a first waveguide section with a first port, a second waveguide section with a second port, and a third waveguide section with a third port, wherein the first and third ports are collinear and the second port is configured as a side port. The second (side) port thereby introduces an electromagnetic asymmetry for the signal propagating between the first and the third ports. That asymmetry may tend to excite higher order waveguide modes.
One way to suppress higher order modes in OMTs, and thus broaden frequency coverage, is to design OMTs that have a symmetric arrangement of waveguide arms, such as disclosed in U.S. Pat. No. 8,816,930. Such symmetric OMTs may, however, be too large and/or cumbersome for many applications, and they may be considered expensive and/or complicated to manufacture.
It would therefore be an advance in the relevant technology to provide a simple, compact waveguide OMT that suppresses excitation of higher order waveguide modes so as to provide high polarization purity and high port-to port isolation, while operating across a broad frequency range.
This disclosure relates to a compact, full band waveguide OMT, comprising first, second, and third waveguide sections. The first waveguide section, which supports propagation of a signal having a first polarization, includes a first conductive wire grid polarization filter (“wire grid polarizer”) that is transparent to the first polarization and reflective to a second polarization that is orthogonal to the first polarization. The second waveguide section, which is configured to support propagation of a signal with the second polarization, includes a second wire grid polarizer that is transparent to the second polarization and reflective to the first polarization. The first and the second waveguide sections transition to the third waveguide section that supports propagation of signals with both the first and second polarizations.
In operation, a radio-frequency signal of a first polarization entering the port of the first waveguide section propagates to the third waveguide section and is received as a signal with the first polarization at the port of the third waveguide section. The signal with the first polarization is prevented from entering the second waveguide section by the second wire grid polarizer. Reciprocally, a radio-frequency signal of a first polarization entering the port of the third waveguide section propagates to the first waveguide section and is received as a signal with the first polarization at the port of the first waveguide section. Again, the signal with the first polarization is prevented from entering the second waveguide section by the second wire grid polarizer.
A radio-frequency signal of a second polarization entering the port of the second waveguide section propagates to the third waveguide section and is received as a signal with the second polarization at the port of the third waveguide section. The signal with the second polarization is prevented from entering the first waveguide section by the first wire grid polarizer. Reciprocally, a radio-frequency signal of a second polarization entering the port of the third waveguide section propagates to the second waveguide section and is received as a signal with the second polarization at the port of the second waveguide section. Again, the signal with the second polarization is prevented from entering the first waveguide section by the first wire grid polarizer.
Among other aspects, the use of wire grid polarizers allows OMTs in accordance with this disclosure to be capable of achieving high polarization purity and high port-to-port isolation across a full waveguide frequency band. Furthermore, these advantageous characteristics may be realized in a compact, easy to manufacture device. These and other features, advantages, and attributes of OMTs in accordance with this disclosure will be more fully understood from the detailed description that follows below.
The frequency band of operation of a rectangular cross-section waveguide (such as the first and second waveguides 12, 14 shown in
In accordance with the US conventional nomenclature, rectangular cross section waveguides are designated as “WRx”, where “x” can be a number between 3 and 2300 denoting the larger of the two cross-sectional waveguide dimensions, with the smaller dimension typically being one-half the larger dimension. Thus, for example, a WR62 waveguide would have a larger inner dimension of 0.622 inches and therefore a smaller dimension of 0.311 inches, and it would typically cover a full frequency band of 12.4-18.0 GHz. This disclosure is not, however, limited to standard waveguide sizes, nor is it limited to any particular waveguide shape.
Referring again to
The second waveguide section 14 extends from a second port 22 to a reduced cross section or “neck” portion 23, terminating in an interior end at which is disposed a second wire grid polarizer 24, at or near the juncture of the three waveguide section 12, 14, 16. The neck portion 23 may be advantageous, in some embodiments, for impedance matching between the second waveguide section 14 and the third waveguide section 16. In some embodiments, an iris, septum, or diaphragm may be used for this impedance matching, as is well known in the waveguide art. The second port 22 is rectangular in some embodiments, with the shorter dimension defining the second electromagnetic wave polarization that is orthogonal to the first polarization.
The third waveguide section 16 extends from a third port 26 to an interior end at which it is joined to the interior ends of the first and second waveguide sections 12, 14. The third port 26 is preferably square, with each side having a length equal to the longer dimension of each of the first port 18 and the second port 22, although other shapes (such as, for example, circular) may be suitable. The configuration (shape and dimensions) of the third port 26 are such as to permit transmission and or reception of signals having either of the first and second polarizations.
The wire grid polarizers 20, 24 are typically made of a grid of conductive wires, as is well known. While wires of circular cross section are typical, other cross-sectional shapes may be considered for use in particular applications. Simplified views of the wire grid polarizers 20, 24 used in accordance with this disclosure are shown in
Providing a wire period P that is much less than the signal wavelength greatly inhibits wave scattering into higher order modes. Specifically, the smaller the period, the greater the reflection of the “undesired” polarization, and therefore the greater the suppression of the excitation of the higher order waveguide modes, thereby yielding high port-to-port isolation and low cross-polarization across a wide frequency range. If the period is too small, however, attenuation of the transmission of the desired polarization may be excessive. The period therefore should be large enough to allow optimum transmission of the desired polarization and to minimize the back reflection (voltage standing wave reflection or “VSWR”) from the grid. Those skilled in the art will readily be able to optimize the grid period and conductor diameter to yield the desired performance for a particular application.
With wire grid polarizers 20, 24 constructed and optimized as described above, signals having a first polarization entering the first port 18 will pass readily through the first wire grid polarizer 20 to the third port 26, while being blocked from entering the second waveguide section 14 by the second wire grid polarizer 24. Similarly, signals having a second polarization orthogonal to the first polarization that enter the second port 22 will readily pass through the second wire polarizer 24 to the third port 26, while being blocked from entering the first waveguide section 12 by the first wire grid polarizer 20.
An impedance-matching element 28 may advantageously be provided in the OMT 10 at or near the juncture of the three waveguide sections 12, 14, 16, as shown in
The first wire grid polarizer 20 is transparent to an electromagnetic signal having a first linear polarization (e.g., along the Y-axis, as defined above), but it is reflective of radiation with a second, orthogonal linear polarization (e.g., along the X-axis, as defined above). Conversely, the second wire grid polarizer 24 is transparent to radiation having the second linear polarization, but it is reflective of a signal having the first linear polarization.
The operation of the OMT 10 is illustrated diagrammatically in
As shown in
From the foregoing, it will be appreciated that if a signal having the first polarization enters the first port 18 of the first waveguide section 12 while a signal having the second polarization enters the second port 22 of the second waveguide section, the signal that is received at the third port 26 of the third waveguide section 16 will have both the first and second polarizations. Conversely, a signal entering the third port 26 of the third waveguide section with both first and second polarizations will result in the component having the first polarization being received in the first port 18 of the first waveguide section 12, and the component having the second orthogonal polarization received at the second port 22 of the second waveguide section 14.
As shown in
It will be appreciated that the polarization filtering provided by the wire grid polarizers 20, 24 is achieved due to the particular oscillation planes of the electric and magnetic fields of the TEio mode of an electromagnetic wave propagating through a rectangular cross section waveguide, as described above.
The results shown in
While preferred embodiments are disclosed herein, variations and modifications of the disclosed embodiments, and, indeed, alternative embodiments, may suggest themselves to those skilled in the pertinent arts. While some variations, modifications, and alternative embodiments have been described or suggested in this disclosure, they are not to be considered exclusive or exhaustive. Such variations, modifications, and alternatives, whether described herein or not, may, in some or all aspects, be equivalents to the subject matter of this disclosure, and should be considered to be encompassed by the claims appended hereto.