| S# |
Lecture |
Course |
Institute |
Instructor |
Discipline |
| 151 |
L39v5: Measuring Wavelength of Light [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 152 |
L35v1: Motivation – Soap Bubble Color
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 153 |
L4v1: Introduce a Driving Force
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 154 |
L39v6: Interference and Diffraction Pattern
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 155 |
L8v8: Examples of Beat Frequencies
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 156 |
L35v2: Superposition of Electric Fields
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 157 |
L4v3: Particular and Homogeneous Solution
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 158 |
L5v1: Coordinate System for a Driven Physical Pendulum
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 159 |
L39v7: Single-slit Diffraction and Double-slit Interference I [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 160 |
L35v3: Average Intensity of the Superposition of Electric Fields
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 161 |
L8v9: General Motion of Coupled Oscillators [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 162 |
L39v8: Single-slit Diffraction and Double-slit Interference II [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 163 |
L35v4: Complex Representation of Fields with a Phase Difference
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 164 |
L5v2: Small Angle Approximation for the Driven Physical Pendulum
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 165 |
L9v1: Review of Normal Modes and Coupled Oscillators
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 166 |
L3v1: Oscillation with a Drag Force
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 167 |
L36v1: Phase Difference from Reflection and Transmission at a Boundary
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 168 |
L9v2: Two Pendula and a Spring
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 169 |
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 170 |
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 171 |
L36v2: Reflected and Transmitted Intensity for a Soap Film
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 172 |
L9v3: Normal Modes and Driven Solution
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 173 |
L5v5: Wine Glass Resonance [DEMO]
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 174 |
L3v4: Critically Damped Motion
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
| 175 |
L36v3: Multiple Reflections from a Soap Film
|
Vibrations and Waves
|
MIT
|
Yen-Jie Lee, Alex Shvonski, Michelle Tomasik
|
Basic and Health Sciences
|
