springs hooke’s law (fs) spring constant (k)
DESCRIPTION
Active Figure 15.1 A block attached to a spring moving on a frictionless surface. (a) When the block is displaced to the right of equilibrium (x > 0), the force exerted by the spring acts to the left. (b) When the block is at its equilibrium position (x = 0), the force exerted by the spring is zero. (c) When the block is displaced to the left of equilibrium (x < 0), the force exerted by the spring acts to the right. At the Active Figures link at http://www.pse6.com, you can choose the spring constant and the initial position and velocities of the block to see the resulting simple harmonic motion.TRANSCRIPT
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Springs
• Hooke’s Law (Fs)
• Spring Constant (k)
• Spring Force – is a restoring force because it always pushes or pulls towards the equilibrium position.
kxFS
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Simple Harmonic Motion
• Simple harmonic motion occurs when the net force along the direction of motion obeys Hooke’s Law – In other words, when the net force is
proportional to the displacement from the equilibrium point and is always directed towards the equilibrium point.
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Fig. 15.3, p.456
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Terminology
• Amplitude (A) – maximum displacement• Period (T) – time it takes the object to
move through one complete cycle• Frequency (f) – the number of complete
cycles per unit of time
• Acceleration (a)
xmka
kxFma
Tf 1
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The Equations
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Equations of Motionfor the object-spring system
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Pendulum Equations
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Types of Traveling Waves
• Transverse wave – the displacement of the wave is perpendicular to the motion of the wave– Sine and cosine graphs– Light waves (electromagnetic waves)
• Longitudinal wave – the displacement of the wave is parallel to the motion of the wave– Sound waves
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Fig. 16.2, p.488
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Fig. 16.5, p.489
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Fig. 16.3, p.488
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Fig. 16.10, p.495
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Terminology and Equations
• Wavelength ()• Wave speed (v)
• Mass per unit length ()
• If the wave is traveling on a string then the wave velocity is defined as:
fT
v
Tv
lm
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Fig. 16.8a, p.492
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IMPORTANT
• There are two different velocities for a traveling transverse wave. – The wave speed, which is literally how fast
the wave is moving to the left or to the right.
– The transverse velocity, which is how fast the wave (rope, string) is moving up and down.
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Wave Interference
• Superposition Principle – when two or more waves encounter each other while traveling through a medium, the resultant wave is found by adding together the displacements of the individual waves point by point.
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Fig. 18.1, p.545
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Fig. 18.2, p.546