Design a Quarter-wave Transformer using a Microstrip Line to Match a 250 Ohm Load to a 75 Ohm transmission Line. The PCB is made of FR-4 and has a thickness of 0.2 mm. Specify Length and width of the strip for a frequency of 2.4 Ghz.
Design a Quarter-wave Transformer using a Microstrip Line to Match a 250 Ohm Load to a...
3. Design a quarter wave transformer to match the following
circuit: Your solution should indicate the required characteristic
impedance of the transformer. Assuming an operating frequency of f
= 5 GHz, and the phase velocity on the line is that of free–space,
(i.e., vp = 3×108 m/s) how long should the transformer be in
mm?
3. Design a quarter wave transformer to match the following circuit: ion should indicate the requir Your solut ed characteristic impedance of the transformer. Assuming...
For a load impedance with ZL = 60-180 Ohm, design two single-stub shunt tuning networks (see Figure a) below) to match this load to a 50 Ohm source; use short-circuited stubs. Calculate transmission line and stub dimensions (length and width) if they are implemented as microstrip lines on FR4 which has thickness of 1.5 mm. ZIZ Figure 1. Single stub tuning circuits: a) shunt sub, b) series stub. (1) A. Behagl, RF and Microwave Circuit Design, Techno Search, 2017. ISBN...
Please answer all parts. Thank you!
(25 points) A half wavelength long 50 Ohm transmission line is terminated with a load of 100 Ohm. The voltage across the load is 16V 2. Determine standing wave ratio on the transmission line. Determine the incident voltage and reflected voltage at the load. Determine the incident current and reflected current a quarter wavelength away from the load. Determine the wave impedance a quarter wavelength away from the load. Design a matching network to...
Design a quarter wavelength network to match a load ZL = 5 ohms to a 50 ohm transmission line at 2GHz? Indicate the characteristic impedance and the line length.
Problem #6: You are tasked to design a 10 GHz microstrip filter using the Rogers RT5870, which has a dielectric constant of 2.33. The substrate has the following thickness (d) options, 0.254 mm, and 1.575 mm. a. For both thickness options, find the line width (W) to obtain a 50 line. (hints assume W/d <2). b. Compute the higher-order resonance frequencies for both thicknesses. Which option gives a higher operation frequency?
USE QUARTER-WAVE METHOD
It is desired to match a 50 Ω line to a load impedance of 60-j50 Ω. Design a 50 (Stub that will achieve the match. Find the length of the line and calculate how far it is from the load. 11.54
[50] You have a load with impedance (10+j10)? at the design frequency, f-100 MHz, that you want to match to a 50? transmission line (v,-3.108m/s). Using Smith charts, construct matching networks using the following elements: (a) a short-circuited parallel stub, (b) an open- circuited parallel stub, (c) a short-circuited series stub, (d) an open-circuited series stub, (e) a quarter-wave transformer. Assume ideal components. Specify the length of each transmission line in meters. ·
microwave communication
Question Soalan 1 A 50Q microstrip line is built on a FR-4 substrate which the specification is given in Table .The line is connected to an ultrasonic sensor of 100 Q Satu garis mikrostrip 50 Q dibina pada substrat FR-4 yang mana spesifikasinya diberikan dalam Jadual 1. Garis ini disambungkan kepada sensor ultrasonik 100 Q Table 1 Jadual 1 Specifications Dielectric Constant Dissipation factor Substrate thickness Copper thickness Surface resistance Operating frequency 2.4 GHz Value 4.7 0.019 1.6...
A 2-section quarter-wave transformer designed to match an unknown real impedance (Z) to a 50 Ω system is shown. The partial reflection coefficients at the TL impedance discontinuities are given. The centre frequency fo is set to be 1 GHz. Estimate Г (magnitude and phase) at 1 GHz and at 1.5 GHz with the simplifying assumption made in class that only the primary partial reflections are relevant to Γ. Ло/4 Zi Z3 Г,-0.15 「= 0.30 Γ,-0.15
please follow instruction and solve every task in detail, thank
you very much!
A generator is connected to a transmission line system that is shown below. The system consists of two transmission lines, each with a characteristic impedance of 75 [2], connected to a load impedance of 75 [2]. These two lines are then fed by a single main feed line having a characteristic impedance 75 [2], which is fed by the generator (not shown). It is desired to have...