RU97116831A - TWO-POLARIZATION WAVEGUIDE DEVICE AND METHOD OF RECEPTION OF SIGNALS - Google Patents

Claims (7)

1. The waveguide device (14), into which at least two orthogonal polarized signals enter, transmitted further along the waveguide, while the waveguide (14) contains: a first pin (20) made out of the waveguide wall (14) inside the waveguide (14 ) in the first meridional plane (28), wherein the aforementioned first pin (20) is used to receive a first signal polarized in the aforementioned first meridional plane (28), reflective means (22) made from the waveguide (14) emerging from the wall (26) and located behind the aforementioned of the first pin (20) along the waveguide (14), while it lies in the aforementioned first meridional plane and serves to reflect the signals polarized in the aforementioned first meridional plane (28), back to the aforementioned first pin (20) and to transmit signals, polarized in a second plane orthogonal to the aforementioned first meridional plane (28), a second pin (24) located behind the reflecting means (22), emerging from the aforementioned wall (26) of the aforementioned waveguide (14) into the aforementioned a waveguide (14) and lying in the aforementioned first meridional plane (28), and signal reflecting and rotating means (30), including a short-circuited circuit (32) at the end of the waveguide (14) and located behind the aforementioned second pin (24), which is used for receiving turning and reflecting a signal polarized in the aforementioned second plane back along the aforementioned waveguide (14), such that the aforementioned reflected and rotated signal is polarized in the aforementioned first meridional plane and received by the aforementioned second pin (24), and the aforementioned first and second pins (20,24) have corresponding first and second outputs brought out of the waveguide (14), wherein the first and second outputs are practically in the aforementioned first meridional plane (28), characterized in that the aforementioned reflection and rotation means (30) has a leading edge oriented at an angle of 45 ° to the aforementioned first meridional plane and made in such a way as to provide at least two sections of the reflecting rib (34a, 34b) on it, the aforementioned sections p The ebras (34a, 34b) are removed at different distances from the aforementioned short-circuited circuit (32) at the end of the aforementioned waveguide (14), whereby part of the aforementioned second signal is reflected from each of the aforementioned sections (34a, 34b) for recombination with a part of the aforementioned second signal, reflected from the aforementioned short-circuited circuit (32), and receiving a signal polarized in the aforementioned first meridional plane, which can be detected by the aforementioned second pin (24).  2. The device according to claim 1, characterized in that on the aforementioned at least two reflective sections (34a, 34b) spaced steps of equal width are made, which are generally orthogonal to the waveguide axis of the waveguide.  3. The device according to claim 1, characterized in that in the areas of the reflecting ribs (34a, 34b) there are three spaced reflecting edges of equal length.  4. Device according to any one of claims 1 to 3, characterized in that the edges (34a, 34b) have different lengths.  5. Device according to any one of claims 1 to 4, characterized in that the reflecting edges (34a, 34b) are orthogonal to the axis of the waveguide and are separated from the short-circuited circuit (32) by a certain distance to minimize signal loss within a given frequency band.  6. The device according to any one of claims 1 to 4, characterized in that an edge non-orthogonal to the axis of the waveguide is made on the reflective edge.  7. A method for receiving at least two signals with orthogonal polarization in the frequency range 10.7-12.75 GHz in one waveguide (14) and performing two outputs in a single meridional plane, comprising the following steps: making the first pin (20) in the first the meridional plane in the aforementioned waveguide (14) for receiving a first signal polarized in the aforementioned first meridional plane, performing reflective means (22) in the aforementioned waveguide located parallel and behind the aforementioned first pin (20), d To reflect the aforementioned first signal and to transmit a second signal polarized in a second plane orthogonal to the aforementioned first meridional plane, execute a second pin (24) in the aforementioned waveguide (14) located parallel and behind the reflective means (22), the aforementioned second pin ( 24) is practically orthogonal to the aforementioned second plane so that signals polarized in the aforementioned second plane pass without receiving them by the aforementioned second pin (24), means for reflecting and rotating a signal (30) located at the end of the waveguide (14) behind the aforementioned second pin (24), with a short-circuited waveguide section (32) located behind the reflecting means (22), for receiving the aforementioned second signal and for reflecting the aforementioned second the signal back along the waveguide (14) in the direction of the aforementioned second pin (24), the aforementioned rotation and reflection means (30) being oriented at an angle of 45 ° to the aforementioned first meridional plane, and the aforementioned second signal also rotates so as to be polarized in the aforementioned first meridional plane and received by the aforementioned second pin (24), as well as the outputs of the first and second pins (20, 24) to the outer surface of the waveguide (14), the outputs being located practically in the aforementioned first the meridional plane, characterized in that the aforementioned method includes the steps of reflecting part of the aforementioned second signal from each of the aforementioned sections of the reflecting ribs (34a, 34b) and part of the aforementioned second signal ala from the above short circuit (32) at the end of the aforementioned waveguide (14), wherein the reflected portion of the signal phase shifted so that they recombine to form a resultant signal in said first longitudinal plane for detection of its aforementioned second pin (24).