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Simple Harmonic Motion

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Presentation on theme: "Simple Harmonic Motion"— Presentation transcript:

1 Simple Harmonic Motion

2 SHM Position, Velocity, and Acceleration

3 Springs and Simple Harmonic Motion

4 Equations of Motion Conservation of Energy allows a calculation of the velocity of the object at any position in its motion…

5 Energy in SHM Energy-time graphs velocity energy KE PE Total
Note: For a spring-mass system: KE = ½ mv2  KE is zero when v = 0 PE = ½ kx2  PE is zero when x = 0 (i.e. at vmax)

6 Energy–displacement graphs
+xo -xo KE PE Total Note: For a spring-mass system: KE = ½ mv2  KE is zero when v = 0 (i.e. at xo) PE = ½ kx2  PE is zero when x = 0

7 Conservation of Energy For A Spring in Horizontal Motion
E = Kinetic Elastic Potential E = ½ mv ½ kx = Constant At maximum displacement, velocity is zero and all energy is elastic potential, so total energy is equal to ½ kxo2

8 Simple Harmonic Motion - Energy
Ek (max) = 1/2mvo2 Ep (max) = 1/2kxo2 Where they happen Ek: max Ep: max max

9 Potential energy in SHM
If a = - ω2x then the average force applied trying to pull the object back to the equilibrium position as it moves away from the equilibrium position is… F = - ½ mω2x Work done by this force must equal the PE it gains (e.g in the springs being stretched). Thus.. Ep (max) = ½ mω2xo2

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