abcd hybrid matrix scattering
Transcription
abcd hybrid matrix scattering
Microwave Engineering Cheng-Hsing Hsu Department of Electrical Engineering National United University Outline 1. Transmission Line Theory 2. Transmission Lines and Waveguides General Solutions for TEM, TE, and TM waves ; Parallel Plate waveguide ; Rectangular Waveguide ; Coaxial Line ; Stripline ; Microstrip 3. Microwave Network Analysis Impedance and Equivalent Voltages and Currents ; Impedance and Admittance Matrices ; The Scattering Matrix ; ABCD Matrix ; Signal Flow Graphs ; Discontinuties and Model Analysis 4. Impedance Matching and Tuning Matching with Lumped Elements ; Single-Stub Tuning ; Double-Stub Tuning ; The Quarter-Wave Transformer ; The Theory of Small Reflections 5. Microwave Resonators Series and Parallel Resonant Circuits ; Transmission Line Resonators ; Dielectric Resonators 6. Power Dividers and Directional Couplers Basic Properties of Dividers and Couplers ; The T-Junction Power Divider ; The Wilkinson Power Divider ; Coupled Line Directional Couplers ; 180o hybrid 7. Microwave Filters Periodic Structure ; Filter Design by the Insertion Loss Method ; Filter Transformations ; Filter Implementation ; 微波工程 Electronic Materials and Devices Applications Lab 6. Power Dividers and Directional Couplers Basic Properties of Dividers and Couplers ; The T-Junction Power Divider ; The Wilkinson Power Divider ; Coupled Line Directional Couplers ; 180o hybrid 微波工程 Electronic Materials and Devices Applications Lab Basic Properties of Dividers and Couplers For the scattering matrix theory, some basic properties of three and four port networks have been discuss and drive. isolation , coupling, and directivity, which are useful quantities for the characterization of couplers and hybrids. 微波工程 Electronic Materials and Devices Applications Lab Three-port Network (T-junctions) The simplest type of power divider is a T-junction, which is three-port network with two inputs and one output. -> the scattering matrix of an arbitrary three network has nine independent elements. S11 S S 21 S 31 S12 S 22 S 32 S13 S 23 S 33 0 S S12 S13 Matched , Reciprocal S12 0 S 23 S13 S 23 0 If the component is passive and contains no anisotropic materials, then it must be reciprocal and its [S] matrix must be symmetric (Sij=Sji). A junction that is lossless and matched at all ports to avoid the power loss. However, three-port network cannot be lossless, reciprocal, and matched at all ports. If the network is also lossless, then energy conservation requires that the scattering matrix be unitary => 2 2 2 2 S12 S13 1 S12 S 23 1 from last three equation at least two of the three parameters (S12, S13, S23) must be zero, but this condition will always be inconsistent with one of 2 2 * S13 S 23 1 S13 S 23 0 first three equation. => if one of these three condition is relaxed, a physical realizable device is possible S * S 0 S * S 0 23 12 12 13 Power division and combining. (a) Power division. (b) Power combining 微波工程 Electronic Materials and Devices Applications Lab If the three-port network is nonreciprocal, then SijSji, and the conditions of input matching at all ports and energy conservation can be satisfied. => a circulator Any matched lossless three-port network for a circulator must be nonreciprocal. => The [S] matrix a matched three-port network has the following form: 0 S S 21 S31 S12 0 S32 S13 Then if the network is lossless, [S] must be unitary 2 2 2 2 => S12 S13 1 S 21 S 23 1 S 23 2 2 * 0 S31 S32 1 S 31 S32 0 * S 21 S 23 0 S12* S13 0 These equations can be satisfied in one of two ways, Either : S12 S 23 S 31 0, Or : S 21 S32 S13 0, S 21 S32 S13 1 S12 S 23 S31 1 This result shows that Sij Sji for ij,which implies that the device must be nonreciprocal. => The [S] matrices for the two solution are shown in figure, together with the symbols for the two possible types of circulators. (port 1to 2, or port 2 to 3, or port 3 to 1 from figure (a) direction) The two types of circulators and their [S] matrices. (The phase references for the ports are arbitrary.) (a) Clockwise circulation. (b) Counterclockwise circulation. 微波工程 Electronic Materials and Devices Applications Lab Alternatively, a lossless and reciprocal three-port network can be physically realized if only two of its ports are matched. 0 S12 S13 S S 0 S If ports 1 and 2 are these matched ports 12 23 S13 S 23 S33 To be lossless, the following unitarity conditions must be satisfied: 2 2 2 S12 S13 1 S13 S 23 S33 1 2 2 2 S12 S 23 1 2 * * S 23 S12 S33 S13 0 the (front end) three equations show │S13│= │S23│ => S13=S23=0 => │S12│=│S33│=1. The signal * S12* S13 S 23 S 33 0 S13* S 23 0 flow graph seen the network actually consists of two separate components, one a matched two-port line and the other a totally mismatched one-port. Finally, if the three-port network is allowed to be lossy, it can be reciprocal and matched at all ports => resistive divider In addition, a lossy three-port can be made to have isolation between its output ports A reciprocal, lossless three-port network matched at ports 1 and 2. 微波工程 Electronic Materials and Devices Applications Lab Four-port Networks (Directional Couplers) The [S] matrix of a reciprocal four-port network matched at all ports has the following form: 0 S S 12 S13 S14 S12 0 S13 S 23 S 23 0 S 24 S 34 S14 If the network is lossless, 10 equations result from the unitarity, or energy conservation, condition. S 24 S34 0 Let us consider the multiplication of row 1 and row 2, and the multiplication of row 4 and row 3 * S13* S 23 S14* S 24 0 and S14* S13 S 24 S 23 0 * * multiply first equation by S 24 and second equation by S13 , and subtract to obtain S14* S13 S 24 2 2 0 (1) Similarly, the multiplication of row 1 and row 3, and the multiplication of row 4 and row 2, * * S12 S 23 S14* S 34 0 and S14* S12 S 34 S 23 0 multiply first equation by S12 and second equation by S34 , and subtract to obtain S 23 S12 S 34 2 2 0 (2) If S14 S 23 0 (1) and (2) to be satisfied directional coupler 微波工程 Electronic Materials and Devices Applications Lab Then the self - products of the rows of the unitary S matrix yield the following equation 2 2 S12 S13 1 2 2 S12 S 24 1 2 2 S13 S34 1 2 2 S 24 S 34 1 which imply that S13 S 24 , and that S12 S34 Further simplification can be made by choosing the phase references on three of four ports. choose S12 S34 α, S ej, and S 24 β ej 13 β where αand βare real, and are phase constants to be determined. * * Dot product of rows 2 and 3 gives S12 S13 S 24 S 34 0 , θ2nπ If we ignore integer multiples of 2, there are two particular choices that commonly occur in practice : ( I ) Symmetrical Coupler /2 ( II ) Antisymmetrical coupler 0, 0 α S jβ 0 α 0 0 jβ jβ 0 0 α 0 jβ α 0 0 α S β 0 α 0 0 β β 0 0 α 0 β α 0 Noted : two couplers differ only in the choice of reference planes. Also, the amplitude αand βare not indenpendent α2 β2 1 thus, apart from te phase references, an ideal directional coupler has only one degree of freedom. 微波工程 Electronic Materials and Devices Applications Lab C 20 log dB D 20 log dB S14 I 20 log S14 dB I D C dB coupling factor S13 β2 2 The ideal coupler would have infinite 2 directivity and isolation (S14=0). Both and through port with the coefficient S12 2 1 β2 could be determined from the coupler factor, C. no power is delivered to port 4 (isolation port ) 微波工程 Electronic Materials and Devices Applications Lab Hybrid couplers are special cases of directional couplers, where the coupling factor is 3 dB, => = = 1/(2)1/2 There are two types of hybrids Quadrature hybrid (90o hybrid) => 90o phase shift between ports 2 and 3 (= = / 2) when fed at port 1, and is an example of a symmetrical coupler. Magic-T hybrid or rat-race hybrid (180o hybrid) => 180o phase difference between ports 2 and 3 when fed at port 4, and is an example of an antisymmetrical coupler. 微波工程 Electronic Materials and Devices Applications Lab Directivity Measurement 微波工程 Electronic Materials and Devices Applications Lab The T - Junction Power Divider The T-junction power divider is a simple three-port network that can be used for power division or power combining, and can be implemented in virtually any type of transmission line medium => commonly used in waveguide, microstrip or stripline structure. (loss or lossless junctions) (a) E plane waveguide T. (b) H plane waveguide T. (c) Microstrip T-junction 微波工程 Electronic Materials and Devices Applications Lab Lossless Divider The lossless T-junction can all be modeled as a junction of three transmission lines. => there are fringing fields and higher order modes associated with the discontinuity at such a junction, leading to stored energy that can be accounted for by a lumped susceptance, B. => divider to be matched to the input line of the characteristic impedance of Zo. If the transmission lines are assumed to be lossless (or of low loss), then the characteristic impedances are real. => assume B = 0 => 1/Z1+1/Z2 = 1/Zo If B is not negligible, some type of reactive tunning element can usually be added to the divider to cancel this susceptance, at least over a narrow frequency range. There will be no isolation between the two output ports, and there will be a mismatch looking into the output ports. 微波工程 Electronic Materials and Devices Applications Lab Ex: A lossless T-junction power divider has a source impedance of 50 . Find the output characteristic impedances so that the input power is divided in a 2:1 ratio. Compute the reflection coefficients seen looking into the output ports. 1 Vo2 Pin 2 Zo 1 Vo2 1 P1 Pin 2 Z1 3 1 Vo2 2 P2 Pin 2 Z2 3 微波工程 Electronic Materials and Devices Applications Lab Resistive (lossy) Divider If a three-port divider contains lossy components it can be made to be matched at all ports, although the two outputs may not be isolated. => using lumped-element resistors to fit the circuit for the divider. => An equal-split (-3dB) divider is form, but unequal power division ratios are also possible. Assuming that all ports are terminated in the characteristic impedance Zo, the impedance Z, seen looking into the Zo/3 resistor followed by the output line, is => Z = Zo/3 + Zo = 4Zo/3 the input impedance of the divider is Zin = Zo/3 + 2Zo/3 = Zo shows that the input is matched to the feed line => the network is symmetric from all three ports, the output ports are also matched. => S11 = S22 = S33 = 0. If the voltage at port 1 is V1, then by voltage division the voltage V at the center of the junction is V V1 2Z o 3 2 V1 Z o / 3 2Z o 3 3 V2 V3 V Zo 3 1 V V1 Z o Z o / 3 4 2 => S21=S31=S23=1/2, which is -6 dB below the input power level => is reciprocal, scattering matrix is symmetric Half of the supplied power is dissipated in the resistors. 微波工程 Electronic Materials and Devices Applications Lab The Wilkinson Power Divider Due to Lossless T-junction divider is not being matched at all ports and doesn’ t have any isolation between output ports, and resistive divider can be matched at all ports (but even though it is not lossless) and still doesn’ t have isolation. However, a lossy three-port network can be made having all ports matched with isolation between the output ports. The Wilkinson power divider is such a network, with the property of being lossless when the output ports are matched; that is, only reflected power is dissipated. (can be made with arbitrary power division, but consider the equal-split 3dB case.) Analyze this circuit by reducing it to two simpler circuits driven by symmetric and antisymmetric sources at the output ports. =>even-odd mode analysis technique. The Wilkinson power divider. (a) An equal-split Wilkinson power divider in microstrip form. (b) Equivalent transmission line circuit. 微波工程 Electronic Materials and Devices Applications Lab Even-odd Mode Analysis Normalize all impedances to the characteristic impedance Zo, and redraw the circuit with voltage generation at the output ports as shown in below figure. (A form that is symmetric across the midplane; the two source resistors of normalized value 2 combine in parallel to give a resistor of normalized value 1. => representing the impedance of a matched source.) quarter-wave lines have a normalized value of Z ; shunt resistor has a normalized value of r => the equal-split power divider, these values should be Z = (2)1/2 and r = 2. we define two separate modes of excitation for the circuit of following figure. Even-mode : Vg2 = Vg3 = 2Vo ; Odd-mode : Vg2 = -Vg3 = 2Vo Using superposition of these two-mode => effectively have an excitation of Vg2 = 4Vo, Vg3 = 0, from which we can find the S-parameters of network. The Wilkinson power divider circuit in normalized and symmetric form. 微波工程 Electronic Materials and Devices Applications Lab Even-mode Even-mode excitation, Vg2 = Vg3 = 2Vo, and so V2e = V3e and there is no current flow through the r/2 resistors or the short circuit between the inputs of two transmission lines at port 1. From the open circuit to form even-mode analysis, the impedance looking into port 2 => Zine = Z2 / 2 since the transmission line looks like a quarter-wave transformer. => If Z = (2)1/2, port 2 will be matched for even mode excitation => V2e = Vo since Zine = 1. If we let x = 0 at port 1 and x = -/4 at port 2, V(x)=V+(e-jx+ejx) V2e = V(-/4) = jV+(1-)=Vo S22e=0 V1e = V(0) = V+(1+) = jVo (+1)/(-1) The reflection coefficient is seen at port 1 = [2-(2)1/2] / [2+(2)1/2] , V1e = -jVo(2)1/2S12e= -j(2)1/2 Symmetry of port 2 and 3=> V3e=Vo ; S33e=0 ; S13e = -j(2)1/2 Bisection of the circuit. (a) Even-mode excitation. (b) Odd-mode excitation. 微波工程 Electronic Materials and Devices Applications Lab Odd-mode Odd-mode excitation, Vg2 = -Vg3 = 2Vo, and so V2o = V3o and there is a voltage null along the middle of the circuit. Thus this circuit by grounding it at two points on its mid-plane. Looking into port 2, an impedance of r/2, since the parallel-connected transmission line is /4 long and shorted at port 1, and looks like an open circuit at port 2. Thus, port 2 will be matched for odd mode excitation if we select r =2. => V2o = Vo and V1o=0 excitation all power is delivered to the r/2 resistors, with none going to port 1. Finally, we must find the input impedance at port 1 of the Winkinson divider when ports 2 and 3 are terminated in matched loads. The resulting circuit is shown in following figure, it is seen that similar to an even mode of excitation, since V2=V3. => no current flows through the resistor of normalized value 2, so it can be removed. We now have the parallel connection of two quarterwave transformers terminated in loads of unity (normalized) => The input impedance is then Zin = [(2)1/2]2/2 =1 Analysis of the Wilkinson divider to find S11. (a) The terminated Wilkinson divider. (b) Bisection of the circuit in (a). 微波工程 Electronic Materials and Devices Applications Lab Summary, we can establish the following S parameters for the Wilkinson divider : S11 0 ( Z in 1 at port 1) ; S 22 S33 0 (ports 2 and 3 matched for even and odd modes) V1e V1o S12 S 21 e j V2 V2o S13 S 31 -j 2 (symmetry due to reciprocity) 2 (symmetry of ports 2 and 3) S 23 S32 0 (due to short or open at biection) When then dividers is driven at port 1 and the outputs are matched, no power is dissipated in the resistor. => the divider is lossless when the outputs are matched; only reflected power from the ports 2 or 3 is dissipated in the resistor. since S23 = S32 = 0 -> ports 2 and 3 are isolated. Photograph of a four-way corporate power divider network using three microstrip Wilkinson power dividers. 微波工程 Electronic Materials and Devices Applications Lab Ex. Design an equal-split Wilkinson power divider for a 50 system impedance at frequency f0, and plot the return loss (S11), insertion loss (S21=S31), and isolation (S23=S32) versus frequency from 0.5f0 to 1.5f0. A characteristic impedance of quarter-wave transmission lines in divider => Z=Z0(2)1/2 = 70.7 , and the shunt resistor a value of R = 2Z0 = 100 Frequency response of an equal-split Wilkinson power divider. Port 1 is the input port; ports 2 and 3 are the output ports 微波工程 Electronic Materials and Devices Applications Lab The quadrature (90o) Hybrid Quadrature hybrid are 3 dB directional couplers with 90o phase difference in the outputs of the though and coupled arm. (often made in microstrip or stripline) -> branch-line hybrid analyze the operation of the quadrature hybrid using an even-odd mode decomposition technique similar to that used for the Wilkinson power divider. The branch-line coupler with all port matched, the power entering port 1 is evenly divided between ports 2 and 3, with a 90o phase shift between these outputs. => No power is coupled to port 4. => the [S] matrix Note: 1. has a high degree symmetry, as any port can be used as the input port 2. output ports always be on opposite side of the junction from the input port 3. isolated port remains on the same side as the input port. 4. this symmetry is reflected in the scattering matrix as each row can be obtained as a transposition of the first row. Geometry of a branch-line coupler. 微波工程 Electronic Materials and Devices Applications Lab Even-odd Mode Analysis The schematic circuit of the branch-line coupler in normalized form as the following figure. => assume that a wave of unit amplitude A1 = 1 is incident at port 1. Because of the symmetry or antisymmetry of the excitation, the four port network can be decomposed into a set of two decoupled two-port network. => since the amplitudes of the incident waves for these two-ports are ±1/2, the amplitudes of the emerging wave at each port of the branch line hybrid can be expressed as : B1 = e / 2 + o / 2 ; B2 = Te / 2 + To / 2 ; B3 = Te / 2 –To / 2 ; B4 = e / 2 - o / 2 Circuit of the branch-line hybrid coupler in a normalized form. 微波工程 Electronic Materials and Devices Applications Lab Firstly, consider the calculation of e and Te , for the even-mode two-port circuit. done by multiplying the ABCD matrices of each cascade component in the circuit. => shunt Y=j /4TL shunt Y=j From ABCD parameters can be convert to S-parameters (Z0 =1) Similarly, with the odd-mode. => B1 = 0 (port 1 is matched) B2 = -j / (2)1/2 (haft-power, -90o phase shift from 1 to 2) B3 = -1 / (2)1/2 (haft-power, -180o phase shift from 1 to 3) B4 = 0 (no power to power 4) Using multi-section BL hybrid => increase BW. Decomposition of the branch-line coupler into even- and odd-mode excitations. (a) Even mode (e). (b) Odd mode (o). 微波工程 Electronic Materials and Devices Applications Lab Coupled Line Directional Couplers When two unshielded transmission lines are close together, power can be coupled between the lines due to the intersection of the electromagnetic fields of each other. Consist of three conductors in close proximity In addition, coupled transmission lines are usually assumed to operate in TEM mode. rigorously valid for stripline structures and approximately valid for microstrip structures. ( a three-wire line can support two distinct propagating modes -> can be used to implement directional couplers, hybrids, and filters.) Various coupled transmission line geometries. (a) Coupled stripline (planar, or edge-coupled). (b) Coupled stripline (stacked, or broadside-coupled). (c) Coupled microstrip. 微波工程 Electronic Materials and Devices Applications Lab Coupled Line Theory If we assume TEM propagation, then the electrical characteristics of the coupled lines can be completely determined from the effective capacitances between the lines and the velocity of propagation on the line. If the strip conductors are identical in size and location relative to the ground conductor, then C11=C22. A three-wire coupled transmission line and its equivalent capacitance network. Consider two special types of excitations for the coupled line: even-mode, where the currents in the strip conductors are equal in amplitude and in the same direction. odd-mode, where the currents in the strip conductors are equal in amplitude but in opposite direction. Even- and odd-mode excitations for a coupled line, and the resulting equivalent capacitance networks.(a) Even-mode excitation. (b) Odd-mode excitation. 微波工程 Electronic Materials and Devices Applications Lab Even - mode : electric field has even symmetry about the center line, and no current flows between the two strip conductors. Lead to the equivalent circuit shown, where C12 is effectively open - circuited. the resulting capacitance of either line to ground for the even mode is Ce C11 C22 assuming that the two strip conductors are identical in size and location characteristic impedance for even - mode is Z 0 e LCe L 1 Ce Ce v p Ce Odd mode : electric field lines have an odd symmetry about the center line, and a voltage null exists between the two strip conductors. imageine this as a ground plane through the middle of C12 effective capacitance between either strip conductor and ground is Co C11 2C12 C22 2C12 1 the characteristic impedance for the odd - mode is Z 0 o v p Co 微波工程 Electronic Materials and Devices Applications Lab For symmetry coupled stripline (support purely TEM mode), the design graph can be used to determine the necessary strip widths and spacing for a given set of characteristic impedance, Z0e, Z0o, and dielectric constant. For microstrip, the results do not scale with dielectric constant, so design graphs must be made for specific values of dielectric constant. Another difficulty with microstrip coupled lines is the fact that the phase velocity is usually different for the two modes of propagation => since the two modes operate with different field configurations in the vicinity of the air-dielectric interface=> degrading effect on coupler directivity. Normalized even- and odd-mode Even- and odd-mode characteristic characteristic impedance design impedance design data for coupled microstrip data for edge-coupled striplines. lines on a substrate with r = 10. 微波工程 Electronic Materials and Devices Applications Lab Design of Coupled Line Couplers Apply an even-odd mode analysis to a length of coupled line to arrive a the design equations. This four-port network is terminated in the impedance Z0 at three of its ports, and driven with a voltage generator of 2Vo and internal impedance Z0 at port 1. => coupler can be designed with arbitrary coupling such that the input (port 1)is matched, while port 4 is isolated. Port 2 is the through port, and port 3 is the coupled port . => a ground conductor is understood to be common to both strip conductors. A single-section coupled line coupler. (a) Geometry and port designations. (b) The schematic circuit. 微波工程 Electronic Materials and Devices Applications Lab The input impedance at port 1 of the coupler can thus be expressed as => Zin = V1/I1 = (V1e+V1o)/(I1e+I1o) => Zin = Z0 Port 1 is matched. Now V1=V0 => the voltage at port 3 is V3 = V3e + V3o = V1e –V1o = V0[(Zine)/(Zine+Z0) –(Zino)/(Zino+Z0)] Z ine Z 0 jZ 0e tan θ where e Z in Z 0 2Z 0 j Z 0e Z 0o tan θ Z ino Z 0 jZ 0o tan θ Z ino Z 0 2Z 0 j Z 0e Z 0o tan θ Decomposition of the coupled line coupler circuit into evenand odd-mode excitation. (a) Even mode. (b) Odd mode. 微波工程 Electronic Materials and Devices Applications Lab If the characteristic impedance, Z0, and the voltage coupling coefficient, C, are specific, then the following design equations for the required even- and odd-mode characteristic impedances can be easily derived. => Z 0 e Z 0 1 C 1 C Z 0 o Z 0 1 C 1 C 微波工程 Electronic Materials and Devices Applications Lab Lange coupler Generally the coupling in a coupled line coupler is too loose to achieve coupling factors of 3 dB or 6 dB. Increasing the coupling between edge-coupled lines is to use several lines parallel to each other, so that the fringing fields at both edges of a line contribute to the coupling. => Lange coupler, four coupled lines are used with interconnections to provide tight coupling, and can easily achieve 3 dB coupling ratios, with an octave or more bandwidth. => There is a 90o phase difference between the output lines (ports 2 and 3) => Lange coupler is a type of quadrature hybrid. The main disadvantage of the Lange coupler is difficult to fabricate the necessary bonding wires across the lines, and the lines are very narrow This type of coupled line is also referred to as interdigitated; can be used for filter design. The Lange coupler. (a) Layout in microstrip form. (b) The unfolded Lange coupler. 微波工程 Electronic Materials and Devices Applications Lab The unfolded Lange coupler operates essentially the same as the original Lange coupler, but is easier to model with the equivalent circuit. => consist of a four-wire coupled line structure => all the lines have the same width and spacing. If the reasonable assumption that each line couples only to its nearest neighbor, and ignore more distant couplings => effectively have a two-wire coupled line circuit. If we can drive the even- and odd- mode characteristic impedances, Ze4, Zo4, of the four-wire circuit in terms of Z0e, and Z0o, the even- and odd-mode characteristic impedances of any adjacent pair of lines. The capacitance of the four lines to ground are different depending on whether the line is on the outside (1 and 4), or on the inside (2 and 3) => Cin = Cex –(CexCm) / (Cex+Cm) Effective capacitance networks for the unfolded Lange coupler Equivalent circuits for the unfolded Lange coupler. (a) Four-wire coupled equivalent circuits. (a) Effective capacitance for the four-wire model. (b) Effective capacitance for the two-wire model. line model. (b) Approximate two-wire coupled line model. 微波工程 Electronic Materials and Devices Applications Lab For even mode excitation, all four conductors are at the same potential, so Cm has no effect and the total capacitance of any line to ground is Ce4 = Cex + Cin. For odd-mode excitation, electric walls effectively exist through the middle of each Cm, so the capacitance of any line to ground is Co4 = Cex + Cin + 6Cm. even- and odd-mode characteristic impedances are Ze4 = 1 / (vpCe4) ; Zo4 = 1 / (vpCo4) Consider any isolated pair of adjacent conductors in the four-line mode; the effectively capacitances are Ce = Cex ; Co = Cex + 2Cm The even-odd mode capacitances of the four-wire line in terms of two-wire coupled line: C 3Ce Co C 3Co Ce Ce 4 e ; Co 4 o Ce Co Ce Co Z Z 0e Z Z 0e Since Z 0 1 v p C Z e 4 0 o Z 0e ; Z o 4 0o Z 0o 3Z 0 o Z 0e 3Z 0 e Z 0 o where Z 0 o , Z 0 e are the odd - and even - mode characteristic impedances of the two - conductor pair. Z 0e Z 0o Z 0 o Z 0 e 3Z 0 o Z 0 e 3Z 0 e Z 0o 2 Z0 Z e 4 Z o 4 Z e 4 Z o 4 3 Z 02e Z 02o while the voltage coupling coefficient is C Z e 4 Z o 4 3 Z 02e Z 02o 2 Z 0 e Z 0 o 4C 3 9 8C 2 Z 0 e Z0 2C 1 C / 1 C ; Z 0o 4C 3 9 8C 2 Z0 2C 1 C / 1 C 微波工程 Electronic Materials and Devices Applications Lab The 180o hybrid The 180o hybrid junction is a four-port network with a 180o phase shift between the two output ports. A signal applied to port 1 will be evenly split into two in-phase components at port 2 and 3, and port 4 will be isolated. => If the input is applied to port 4, it will be equally split into two components with a 180o phase difference at ports 2 and 3, and port 1 will be isolated. When operated as a combiner, with input signals applied at ports 2 and 3, the sum of the inputs will be formed at port 1, while the difference will be formed at port 4. => ports 1 and 4 are referred to as the sum and difference ports, respectively. The scattering matrix for the ideal 3 dB 180o hybrid => unitary and symmetry Hybrid junctions. (a) A ring hybrid, or rate-race, Symbol for a 180° hybrid junction. in microstrip or stripline form. (b) A tapered coupled line hybrid. (c) A waveguide hybrid junction, or magic-T. 微波工程 Electronic Materials and Devices Applications Lab Even-odd Mode Analysis Consider a unit amplitude wave incident at port 1 (the sum port). => the ring junction this wave will divide into two components, which both arrive in phase at ports 2 and 3, and 180o out of phase at port 4. Using the even-odd mode analysis technique, decompose this case into a superposition of the two simpler circuits and excitations. Amplitudes of the scattered waves : B1 = e / 2 +o / 2 ; B2 = Te / 2 + To / 2 ; B3 = e / 2 - o / 2 ; B4 = Te / 2 –To / 2 Even- and odd-mode decomposition of the ring hybrid when port 1 is excited with a unit amplitude incident wave. (a) Even mode. (b) Odd mode. 微波工程 Electronic Materials and Devices Applications Lab Using the ABCD matrix for even- and odd-mode two-port circuits to evaluate the required reflection and transmission coefficients. B1 = 0 ; B2 = -j / (2)1/2 ; B3 = -j / (2)1/2 ; B4 = 0 => the input port is matched, port 4 is isolated, and the input power is evenly divided and in phase between ports 2 and 3. 微波工程 Electronic Materials and Devices Applications Lab Consider a unit amplitude wave incident at port 4 (the difference port). => the two wave components on the ring will arrive in phase in phase at ports 2 and 3, with a net phase difference of 180o between these ports. Amplitudes of the scattered waves : B1 = Te / 2 –To / 2; B2 = e / 2 - o / 2; B3 = Te / 2 + To / 2; B4 = e / 2 +o / 2 Even- and odd-mode decomposition of the ring hybrid when port 4 is excited with a unit amplitude incident wave. (a) Even mode. (b) Odd mode. 微波工程 Electronic Materials and Devices Applications Lab Using the ABCD matrix for even- and odd-mode two-port circuits to evaluate the required reflection and transmission coefficients. A B 1 j 2 A B 1 ; C D C D 1 j 2 j 2 e o j j j j e , Te , o , To 2 2 2 2 j j B1 0, B2 , B3 , B4 0 2 2 j 2 1 Input port is matched, port 1 is isolated, and the input power is evenly divided into ports 2 and 3 with a 180o phase difference. The bandwidth of the ring hybrid is limited by the frequency dependence of the ring lengths, bur is generally on the order of 20~30% => increasing the BW additional sections or a symmetric ring circuit. 微波工程 Electronic Materials and Devices Applications Lab 微波工程 Electronic Materials and Devices Applications Lab