Strip lines
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15 slides
May 02, 2010
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STRIP LINES
Microwave transmission lines
•Coaxial cables
•Waveguides
•Striplines
–Microstriplines
–Parallel strip-lines
–Coplanar strip lines
–Shielded strip lines
•Coaxial cables
•Waveguides
•Striplines
–Microstriplines
–Parallel strip-lines
–Coplanar strip lines
–Shielded strip lines
Microstriplines
•Microwave solid-state device can be easily fabricated as a
semiconducting chip
•Very less volume of the order of 0.008-0.08mm
3
•Mode of transmission-quasi TEM, hence the theory of
TEM-coupled lines is approximated.
•Microwave solid-state device can be easily fabricated as a
semiconducting chip
•Very less volume of the order of 0.008-0.08mm
3
•Mode of transmission-quasi TEM, hence the theory of
TEM-coupled lines is approximated.
Deriving Z
oof microstriplines
Comparison method
Comparing with a wire over ground,
For a wire over ground,
Changes for microstriplines,
The effective permittivity will be
Other relation will be
t/w<0.8
[derived by Assadourian]
oof microstriplines
Comparison method
Comparing with a wire over ground,
For a wire over ground,
Changes for microstriplines,
The effective permittivity will be
Other relation will be
t/w<0.8
[derived by Assadourian]
The velocity of propagation of microwaves in microstrips,
Propagation time constant is,
??????
�=μ ϵ
=3.333ϵ
?????? �??????/�
LOSSES IN MICROSTRIP LINES
•OhmicLosses
•Dielectric Losses
•Radiation Losses
Typically, Z
ois in between 50Ωto 150Ω
Propagation time constant is,
??????
�=μ ϵ
=3.333ϵ
?????? �??????/�
LOSSES IN MICROSTRIP LINES
•OhmicLosses
•Dielectric Losses
•Radiation Losses
Typically, Z
ois in between 50Ωto 150Ω
Power losses in Microstrips
•The power carried by a wave travelling in z direction is given by
•The attenuation constant αcan be expressed as
•Power dissipation per unit length can be calculated as
•The power carried by a wave travelling in z direction is given by
•The attenuation constant αcan be expressed as
•Power dissipation per unit length can be calculated as
•Hence,
Dielectric loss
from first unit,
Attenuation constant, ∝=
σ
2
μ
ε
Phase constant,??????=??????μϵ
Here,
∝
??????=
σ
2
μ
ε
Np/m
Np/m
Dielectric attenuation constant,
Substituting
We get, [Welch and pratt’sequation]
Dielectric loss
from first unit,
Attenuation constant, ∝=
σ
2
μ
ε
Phase constant,??????=??????μϵ
Here,
∝
??????=
σ
2
μ
ε
Np/m
Np/m
Dielectric attenuation constant,
Substituting
We get, [Welch and pratt’sequation]
Modified equation by Pucel,
dB/m Where,
We usually express ∝
??????in dB/λ
g
Where,
dB/m Where,
We usually express ∝
??????in dB/λ
g
Where,
Ohmicloss
•Because of the resistance in path
•Mainly due to irregularities in conductors
•Current density mainly concentrated in a sheet with a thickness equal to skin depth
•Current distribution in a microstripis as in diagram,
•Exact expressions for conducting attenuation constant
can not be determined.
•Assuming current distribution is uniform,
dB/m
Above relation holds good only if w/h<1
•Because of the resistance in path
•Mainly due to irregularities in conductors
•Current density mainly concentrated in a sheet with a thickness equal to skin depth
•Current distribution in a microstripis as in diagram,
•Exact expressions for conducting attenuation constant
can not be determined.
•Assuming current distribution is uniform,
dB/m
Above relation holds good only if w/h<1
Radiation losses
•Depends on substrate’s thickness, its dielectric constant and
its geometry.
•Some approximations:
–TEM transmission
–Uniform dielectric
–Neglecting TE field component
–Substrate thickness<<free space λ
•The ratio of radiated power to total dissipated power is
Where,
•Depends on substrate’s thickness, its dielectric constant and
its geometry.
•Some approximations:
–TEM transmission
–Uniform dielectric
–Neglecting TE field component
–Substrate thickness<<free space λ
•The ratio of radiated power to total dissipated power is
Where,
Quality factor
•Quality factor of the striplinesis very high, but limited by radiation losses
of the substrates.
•Q
cis related to conductor attenuation constant by,
•Substituting, dB/λ
g
•??????
�=3.95??????10
−6
ℎ
????????????
??????
•Substituting R
sand ??????=5.8??????10
7
mho/m for copper assuming striplineis in air,
??????
�=15.14ℎ??????
•Similarly, Q
drelated to dielectric attenuation constant is given by,
approximating,
•Quality factor of the striplinesis very high, but limited by radiation losses
of the substrates.
•Q
cis related to conductor attenuation constant by,
•Substituting, dB/λ
g
•??????
�=3.95??????10
−6
ℎ
????????????
??????
•Substituting R
sand ??????=5.8??????10
7
mho/m for copper assuming striplineis in air,
??????
�=15.14ℎ??????
•Similarly, Q
drelated to dielectric attenuation constant is given by,
approximating,
Parallel strip lines
•Two perfectly parallel strips separated by a perfect dielectric
slab of uniform thickness.
•Considering w>>d,
some parameters are
•Two perfectly parallel strips separated by a perfect dielectric
slab of uniform thickness.
•Considering w>>d,
some parameters are
Attenuation losses
•The propagation constant of a parallel strip is,
The attenuation constant will be
•The propagation constant of a parallel strip is,
The attenuation constant will be
•Coplanar striplines
•Shielded striplines
•Shielded striplines
THANK YOU!
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