Microwave technology basics

1. Introduction (2 hours)
Microwaves and their characteristics; Applications of microwave technology; Navigation waves and their general transmission characteristics;
2. Transmission line theory (10 hours)
Transmission line equations and their solutions; Distributed parameter impedance; Analysis of working conditions of lossless transmission lines; Characteristics and calculations of lossy lines; Smith chart; impedance matching.
3. Regular metal waveguide (6 hours)
Rectangular waveguide; circular waveguide; coaxial line; normal scale characteristics of waveguide.
4. Microwave integrated transmission lines (8 hours)
Conformal transformation method for calculating the characteristic impedance of transmission lines; strip lines; coupled strip lines and coupled microstrip lines; other types of planar transmission lines.
5. Dielectric waveguides and optical fibers (4 hours)
Surface waves and their characteristics; simple dielectric waveguides; dielectric mirror lines; optical fibers; thin film optical fiber waveguides and ribbon optical waveguides.
6. Microwave network basics (8 hours)
equivalent network of microwave joints; impedance characteristics of one-port network; impedance and admittance matrix; scattering matrix; transfer parameter matrix; transmission scattering matrix; signal flow diagram method.
7. Microwave resonator (10 hours)
Basic characteristics and parameters of microwave resonator; transmission line resonator; metal waveguide resonant cavity; dielectric resonator; Fabry-Ross resonator; resonator excitation; perturbation theory of resonant cavity .
8. Commonly used microwave components (6 hours)
: waveguide mode excitation devices; commonly used microwave components; microwave periodic structures; microwave ferrite isolators and circulators.

• Chapter 1：Introduction 1 (47 minutes and 58 seconds)

• Chapter 2：Introduction 2 (39 minutes and 31 seconds)

• Chapter 3：Transmission Line Equation 1 (49 minutes and 18 seconds)

• Chapter 4：Transmission Line Equation 2 (48 minutes and 41 seconds)

• Chapter 5：Transmission status analysis 1_1 (43 minutes and 46 seconds)

• Chapter 6：Transmission status analysis 1_2 (48 minutes and 34 seconds)

• Chapter 7：Transmission status analysis 1_3 (44 minutes and 58 seconds)

• Chapter 8：Transmission status analysis 2_1 (45 minutes and 48 seconds)

• Chapter 9：Complex theta theory 1 (42 minutes and 55 seconds)

• Chapter 10：Complex theta theory 2 (49 minutes and 45 seconds)

• Chapter 11：Transmission line matrix solution 1 (44 minutes and 23 seconds)

• Chapter 12：Transmission line matrix solution 2 (48 minutes and 0 seconds)

• Chapter 13：Smith chart 1 (49 minutes and 34 seconds)

• Chapter 14：Smith chart 2 (47 minutes and 16 seconds)

• Chapter 15：Impedance matching 1 (48 minutes and 7 seconds)

• Chapter 16：Impedance matching 2 (47 minutes and 18 seconds)

• Chapter 17：Transmission line computer solution 1 (44 minutes and 9 seconds)

• Chapter 18：Transmission line computer solution 2 (43 minutes and 12 seconds)

• Chapter 19：Example explanation 1_1 (55 minutes and 14 seconds)

• Chapter 20：Example explanation 1_2 (33 minutes and 24 seconds)

• Chapter 21：Generalized transmission line theory 1 (44 minutes and 17 seconds)

• Chapter 22：Generalized transmission line theory 2 (28 minutes and 10 seconds)

• Chapter 23：Rectangular waveguide 1_1 (53 minutes and 9 seconds)

• Chapter 24：Rectangular waveguide 1_2 (41 minutes and 4 seconds)

• Chapter 25：Rectangular waveguide 2_1 (42 minutes and 46 seconds)

• Chapter 26：Rectangular waveguide 2_2 (46 minutes and 59 seconds)

• Chapter 27：Guided Wave Concept 1 (43 minutes and 37 seconds)

• Chapter 28：Guided Wave Concept 2 (42 minutes and 11 seconds)

• Chapter 29：Circular waveguide 1_1 (49 minutes and 59 seconds)

• Chapter 30：Circular waveguide 1_2 (41 minutes and 29 seconds)

• Chapter 31：Circular waveguide 2_1 (41 minutes and 13 seconds)

• Chapter 32：Circular waveguide 2_2 (48 minutes and 21 seconds)

• Chapter 33：Eigenmode theory 1 (38 minutes and 11 seconds)

• Chapter 34：Eigenmode theory 2 (44 minutes and 0 seconds)

• Chapter 35：coaxial line (47 minutes and 19 seconds)

• Chapter 36：conformal transformation (51 minutes and 36 seconds)

• Chapter 37：Coaxial line and strip line 2_1 (47 minutes and 34 seconds)

• Chapter 38：Coaxial line and strip line 2_2 (41 minutes and 49 seconds)

• Chapter 39：Microstrip 1 (47 minutes and 57 seconds)

• Chapter 40：Microstrip 2 (42 minutes and 29 seconds)

• Chapter 41：Fiber optic concept 1 (45 minutes and 41 seconds)

• Chapter 42：Fiber optic concept 2 (44 minutes and 13 seconds)

• Chapter 43：Coupled transmission line 1 (46 minutes and 56 seconds)

• Chapter 44：Coupled transmission line 2 (43 minutes and 55 seconds)

• Chapter 45：Course content review 1_1 (46 minutes and 41 seconds)

• Chapter 46：Course content review 1_2 (40 minutes and 3 seconds)

• Chapter 47：Single port component 1 (43 minutes and 22 seconds)

• Chapter 48：Single port component 2 (41 minutes and 24 seconds)

• Chapter 49：Dual port component 1 (41 minutes and 38 seconds)

• Chapter 50：Dual port component 2 (48 minutes and 27 seconds)

• Chapter 51：Multi-port component 1 (43 minutes and 51 seconds)

• Chapter 52：Multi-port component 2 (44 minutes and 58 seconds)

• Chapter 53：Rectangular cavity 1 (44 minutes and 5 seconds)

• Chapter 54：Rectangular cavity 2 (46 minutes and 21 seconds)

• Chapter 55：cavity theory 1 (49 minutes and 0 seconds)

• Chapter 56：cavity theory 2 (44 minutes and 58 seconds)

• Chapter 57：Transmission line cavity 1 (35 minutes and 44 seconds)

• Chapter 58：Transmission line cavity 2 (51 minutes and 2 seconds)

• Chapter 59：Coupling cavity 1 (42 minutes and 44 seconds)

• Chapter 60：Coupling cavity 2 (45 minutes and 4 seconds)

• Chapter 61：Perturbation method 1 (52 minutes and 18 seconds)

• Chapter 62：Perturbation method 2 (36 minutes and 33 seconds)

• Chapter 63：Course content review 2_1 (41 minutes and 33 seconds)

• Chapter 64：Course content review 2_2 (35 minutes and 49 seconds)