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Mechanics: Simple Harmonic Motion

S#	Lecture	Course	Institute	Instructor	Discipline
1	Deep Dive – Integrate Energy to Find the Simple Harmonic Motion Solution	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
2	Deep Dive – Spring with a Different Coordinate System	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
3	L39v1: Simple Harmonic Motion – Equation of Motion	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
4	L39v2: Simple Harmonic Motion – Guess a Solution to the Differential Equation	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
5	L39v3: Simple Harmonic Motion – Find the Solution Using Initial Conditions	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
6	L40v1: Simple Harmonic Motion Solution with Amplitude and Phase	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
7	L40v2: Amplitude, Phase, and Period	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
8	L40v3: Graphical Representations of Velocity and Acceleration	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
9	L40v4: Value of the Phase Constant in SHM	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
10	L41v1: Energy Conservation for the Spring	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
11	L41v2: Using Energy in Different Contexts	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
12	L41v3: Derivition of the SHM Equation from Energy	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
13	L41v4: Generalized Energy in SHM	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
14	L41v6: Worked Example – U-tube	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
15	L42v1: Expand Cosine with the Taylor Formula	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
16	L42v5: Physical Pendulum	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
17	L43v1: Strategy for Small Oscillation Problems	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences
18	Simple Pendulum with Initial Conditions at a Quarter Period	Mechanics: Simple Harmonic Motion	MIT	Peter Dourmashkin, Deepto Charkrabarty,Michelle Tomasik, Analia Barrantes, Aidan MacDonagh	Basic and Health Sciences