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Microwave Network Analysis

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Chapter 4 Microwave Network Analysis Problem3: Design a 6GHz attenuator ? (Hint: -20logS21=6 S21=0.501 ) Problem4: Design a 6nH ... – PowerPoint PPT presentation

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Title: Microwave Network Analysis


1
Chapter 4
  • Microwave Network Analysis

2
Equivalent Voltage and Current
  • For non-TEM lines, the quantities of voltage,
    current, and impedance are nor unique, and are
    difficult to measured. Following considerations
    can provide useful result
  • 1) Voltage and current are defined only for a
    particular mode, and are defined so that the
    voltage is proportional to the transverse
    electric field, and the current is proportional
    to transverse magnetic field.
  • 2) The product of equivalent voltage and current
    equals to the power flow of the mode.
  • 3) The ratio of the voltage to the current for a
    single traveling wave should be equal to the
    characteristic impedance of the line. This
    impedance is usually selected as equal to the
    wave impedance of the line.

3
The Concept of Impedance
  • Various types of impedance
  • 1) ?(?/?)1/2 intrinsic impedance of medium.
    This impedance is dependent only on the material
    parameters of medium, and is equal to the wave
    impedance of plane wave.
  • 2) ZwEt /Ht1/Yw wave impedance, e.g. ZTEM,
    ZTM, ZTE. It may depend on the type of line or
    guide, the material, and the operating frequency.
  • 3) Z0 (L /C)1/2 1/Y0 characteristic
    impedance. It is the ratio of voltage to current.
    The characteristic impedance is unique definition
    for TEM mode but not for TM or TE modes.
  • The real and imaginary parts of impedance and
    reflection coefficient are even and odd in ?0
    respectively.

4
Impedance and Admittance Matrices
  • The terminal plane (e.g. tN) is important in
    providing a phase reference for the voltage and
    current phasors.
  • At the nth terminal (reference) plane, the
    relations are given as
  • Reciprocal Networks
  • If the arbitrary network is reciprocal ( no
    active devices, ferrites, or plasmas), Y and
    Z are symmetric matrices .

5
  • Lossless Networks
  • If the arbitrary network is lossless, then the
    net real power delivered to the network must be
    zero. Besides

Example4.1 Find the Z parameters of the two-port
network?
Solution
6
The Scattering Matrices
  • The scattering parameter Sij is the transmission
    coefficient from j port to port i when all other
    ports are terminated in matched loads.
  • Z or Y ? S
  • S ? Z

7
Example4.2 Find the S parameters of the 3 dB
attenuator circuit?
Solution
A matched 3B attenuator with a 50 O
Characteristic impedance
8
  • Reciprocal Networks
  • Lossless Networks
  • No real power delivers to network.Besides
  • S is symmetric matrix

Example4.3 Determine if the network is
reciprocal, and lossless? If port 2 terminated
with a matched load, what is the return loss at
port 1? If port 2terminated with a short circuit,
what is the return loss seen at port 1?
Solution
  • Since S is not symmetric, the network is not
    reciprocal.
  • So the network is not lossless.

9
When port 2 terminated with a matched load,
?S110.15.
When port 2 terminated with a short circuit,
10
Summary
  • Reciprocal Networks (symmetric)
  • No active elements, no anisotropic material
  • Lossless Networks
  • No resistive material, no radiation

11
Example4.4 Determine if the network is
reciprocal, and lossless ?
Solution
From the result of example 4.2
A matched 3B attenuator with a 50 O
Characteristic impedance
Since the network is reciprocal but not lossless,
S should be symmetric but not unitary.
Since the network is reciprocal but not lossless,
Z should be symmetric but not imaginary.
12
Example4.5 Determine if the network is
reciprocal, and lossless ?
Solution
13
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14
  • Problem 1Determine if the inductance networks
    are reciprocal, and lossless ?
  • Problem 2Determine if the capacitance networks
    are reciprocal, and lossless ?

15
Three Port Network
  • Reciprocal Network
  • Matching at all ports
  • Lossless Network

16
Applications
  • A counter-clockwise circulator
  • S is unitary and matched at all ports, but not
    symmetric. Therefore, circulator is lossless and
    matched, but not reciprocal.
  • Power splitters
  • S is symmetric and matched at all ports, but
    not unitary. Therefore, circulator is reciprocal
    and matched, but not lossless.

17
  • A Shift in Reference Planes
  • Twice the electric length represents that the
    wave travels twice over this length upon
    incidence and reflection.
  • Generalized Scattering
  • Parameters
  • If the characteristic impedances of a multi-port
    network are different,

18
Generalized Scattering Matrices
  • The scattering parameter Sij defined earlier was
    based on the assumption that all ports have the
    same characteristic impedances ( usually Z050?).
    However, there are many cases where this may not
    apply and each port has a non-identical
    characteristic impedance.
  • A generalized scattering matrix can be applied
    for network with non-identical characteristic
    impedances, and is defined as following

19
The Transmission (ABCD) Matrix
  • ABCD matrix has the advantage of cascade
    connection of multiple two-port networks.

20
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21
  • Table 4-2 Conversions between two-port network
    parameters

22
  • For reciprocal network, Z is is symmetric.
    Hence, Z12Z21

Example4.6 Find the S parameters of network?
Solution
  • From Table 4-1

23
  • From Table 4-2

24
The Transmission T Matrix
  • At low frequencies, ABCD matrix is defined in
    terms of net voltages and currents. When at high
    frequencies, T matrix defined in terms of
    incident and reflected waves will become very
    useful to evaluate cascade networks.

25
Equivalent Circuit for Two-Port Networks
A coax-to-microstrip transition and equivalent
circuit representations. (a) Geometry of the
transition. (b) Representation of the transition
by a black box. (c) A possible equivalent
circuit for the transition.
26
  • Equivalent circuits for some common microstrip
    discontinuities. (a) Open-ended. (b) Gap. (c)
    Change in width. (d) T-junction.

27
  • Equivalent circuits for a reciprocal two-port
    network.
  • (a) T equivalent (b) ? equivalent

28
Example4.7 Find the network as equivalent T and
? model at 1GHz?
Solution
  • From Table 4-1
  • From Table 4-2

29
Equivalent T model
  • From Table 4-2

Equivalent ? model
30
Example4.8 Find the equivalent ? model of
microstrip-line inductor?
Solution
  • From Table 4-1
  • From Table 4-2

31
Equivalent ? model
32
Example4.9 Find the equivalent T model of
microstrip-line capacitor?
Solution
  • From Table 4-1
  • From Table 4-2

33
Equivalent T model
34
  • Problem3 Design a 6GHz attenuator ?
  • (Hint -20logS216 ? S210.501
    )
  • Problem4 Design a 6nH microstrip-line inductor
    on a 1.6mm thick FR4 substrate. The width of line
    is 0.25mm. Find the length (l ) and parasitic
    capacitance?
  • Problem5 Design a 2pF microstrip-line capacitor
    on a 1.6mm thick FR4 substrate. The width of line
    is 5mm. Find the length (l ) and parasitic
    inductance?
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