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Theoretical Information About Ring Hybrid Junction | ||||
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Ring Hybrid junction is a four-port network with a 180 degree phase shift between two output ports but it can also be operated so that output ports are in phase. The 180 degree ring hybrid can be constructed in several forms such as planar form or other forms like wave guide forms. In this toolkit we shall only deal with planar forms, i.e. microstrip and stirpline forms (see figures below for planar forms)
Here we will use most famous method while analyzing the ring hybrid, that is even-odd mode analysis. However, before going through the detail of even-odd mode analysis, the relation between impedance and width over depth ratio for transmission lines will be explored, which plays a very crucial role in our ring hybrid design process. Relation between impedance and width over depth ratio for transmission lines For ring hybrid design in our analysis one must necessarily drop in the panel, where the impedance values are derived from entered width over depth ratios or vice versa. Because we think that those geometric information about the line from which we construct our ring hybrid junction has much importance. In that panel user has two options. S/he might enter impedance values and obtain width over depth ratios from them or vice versa. The formulas used for these calculations are different for stripline and microstrip. Let's analyze the case as follows: εr : dielectric constant A-For stripline:
A-2 If width over depth ratio(W/d) is entered
B- For microstrip:
B-2 If width over depth ratio(W/d) is entered so to sum up using those formulas W/d ratios are returned
to user when he entered impedance values and impedance values are returned
to user when he entered the W/d ratios for transmission lines that form
the ring hybrid junction. Even-Odd Mode Analysis of the Ring Hybrid
Above you see a detailed
image of the ring hybrid junction and the variables related to it are
also shown
For even-mode excitation. for odd mode excitation. Then from those pictures we see that the amplitude of scattering waves from the ring will be
Then we can evaluate the required reflection and transmission coefficients defined as in the figures above, showing even and odd mode cases, using the ABCD matrix for the even and odd mode two-port circuits in those figures. Then from there the results are equal to matrix multiplication of three matrices as follows
so the result is
so the result is
for the odd-mode excitation. Then with the aid of a conversion table from ABCD matrix to reflection and transmission coefficients
which shows that the input port is matched, poet 4 is isolated, and the input power is evenly divided in phase between ports 2 and 3. These results also form the first row and first column of the scattering matrix. Now consider a unity amplitude wave incident at port
4 (difference port)of the ring hybrid junction. The two wave components
on the ring will arrive in phase at ports and 3, with a net phase difference
of 180 degree between these ports. The two wave components will be 180
degree out of phase at port1. This case can be decomposed into a superposition
of the two simpler circuits and excitations for the even mode
for the odd mode case. Then the amplitudes of the scattered waves will become
then the ABCD matrices for the even and odd mode circuit of the figures above
so the result is
for the even-mode excitation case.
so the result is
for the odd-mode excitation. Then using a conversion table
which shows that the input port is
matched, port 1 is isolated, and the input power is evenly divided into
ports 2 and 3 with a phase difference of 180 degree. These results form
the fourth row and column of the scattering matrix and the other remaining
elements can be found from symmetry considerations. |
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