Electromagnetic Waves:
Design single stub matching network for the transmission line of Zo
= 50 ohms...
Electromagnetic Waves:
Design single stub matching network for the transmission line of Zo
= 50 ohms terminated with Z1 = 100+ j100 ohms. Find SWR and
Reflection Coefficient .
A 100 ohms load is connected to a 50 ohms transmission line.
Determine the value of the reactance to put in series at the input
to the line and the length in wavelengths of the shortest
transmission line to match with a 50 ohms source.
a single stub tuner, connected in parallel, has a 50 ohm main
line, and a 50 ohm short- circuited stub .It is used to match a
load of Zr = 20+j70 to a 50 ohm system. What are the lengths of the
line and stub in centimeters if the single stub tuner is using air
filled coaxial lines and the system is operating at 600MHz
Assume a transmission line with ZL = 65 + j40Ω and Zo = 30Ω. If
the frequency of the
line is 2GHz, use the Smith Chart to find: i) the reflection
coefficient; ii) the distance to the
first voltage maximum; iii) the voltage standing wave ratio; iv) the
admittance of the load;
v) the position of the short-circuited stub on the main line for a
perfect impedance matching;
vi) the length of the short-circuited stub. (Show all steps on the...
Assume a transmission line with ZL = 65 + j40 Ω and Zo = 30 Ω.
If the frequency of the line is 2GHz, use the Smith Chart to find:
i) the reflection coefficient; ii) the distance to the first
voltage maximum; iii) the voltage standing wave ratio; iv) the
admittance of the load; v) the position of the short-circuited stub
on the main line for a perfect impedance matching; vi) the length
of the short-circuited stub. (Show all steps...
Assume a transmission line with ZL = 65 + j40 Ω and Zo = 60 Ω.
If the frequency of the line is 2GHz, use the Smith Chart to find:
i) the reflection coefficient; ii) the distance to the first
voltage maximum; iii) the voltage standing wave ratio; iv) the
admittance of the load; v) the position of the short-circuited stub
on the main line for a perfect impedance matching; vi) the length
of the short-circuited stub. (Show all steps...
A lossless 50-Ω transmission line is terminated in a load
with
Z L = (35 − j47.5) Ω using a short circuited stub. Use the Smith
chart to determine position and
length line for the stub?
show step by step by hand and draw by hand
I want details so I can understand
A lossless 50-Ω transmission line is terminated in a load
with
Z L = (35 − j47.5) Ω using a short circuited stub. Use the Smith
chart to determine position and
length line for the stub?
show step by step
I want details so I can understand
Assume a transmission line with ZL = 100 − j25 Ω and Z0 = 50 Ω.
Using the smith chart, find i) the normalised load impedance; ii)
the corresponding reflection coefficient; iii) the standing wave
ratio; iv) the distance between the load and the first voltage
maximum; v) the distance between the load and the first voltage
minimum; vi) the normalised admittance;
vii) the input impedance at 0.2λ from the load. (Show all steps
on the Smith chart)
I'm working on a project where I need to design a transmission
line tap for a station generator. The parameters include sizing
three switches for the tap where at least one is a loop break
switch. From where to start? What kind of calculations are needed
to size the switches? What are those switches?
8.
A 100 W load is connected to a 50 W transmission line. Determine
the value of the reactance to put in series at the input to the
line and the length in wavelengths of the shortest transmision line
to match with a 50 W source.