| S# |
Lecture |
Course |
Institute |
Instructor |
Discipline |
| 76 |
L29v4: Total Internal Reflection
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 77 |
L1v1: Equation of Motion for a Horizontal Block and Spring
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 78 |
L24v4: Delta Function to Extract the Fourier Transform Weights
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 79 |
L29v5: Total Internal Reflection [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 80 |
L1v2: Motion of the Mass from Initial Conditions
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 81 |
L2v1: Complex Notation to Describe Simple Harmonic Motion
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 82 |
L25v1: Idea for Transmission of AM Signals
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 83 |
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 84 |
L25v2: Functional Form of AM Signal Transmission
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 85 |
L2v2: Properties of Complex Numbers
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 86 |
L1v4: Release Angle of Pendulum [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 87 |
L2v3: Energy in the Simple Harmonic Oscillator
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 88 |
L25v3: Review of How AM Signals Transmit
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 89 |
L1v5: Multiple Potential Well [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 90 |
L31v3: Single Photon Source
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 91 |
L26v1: Review of Fourier transform properties
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 92 |
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 93 |
L31v4: Creating Circularly Polarized Waves Usig Wave Plates
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 94 |
L26v2: Define the Spread of Time and Frequency
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 95 |
L2v5: Different Physical Pendula [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 96 |
L26v3: Calculation of the Spread of Frequency
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 97 |
L31v5: Quarter Wave Plate
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 98 |
L30v1: Electric Field in EM wave
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 99 |
L30v2: Linearly Polarized Waves
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 100 |
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
