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Physics 12 Resource: Giancoli Chapter 11. Kinematics of simple harmonic motion (SHM). Objectives. Describe examples of oscillations Define the terms displacement, amplitude, frequency, period and phase difference. Define simple harmonic motion (SHM) .
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Physics 12 Resource: Giancoli Chapter 11 Kinematics of simple harmonic motion (SHM)
Objectives • Describe examples of oscillations • Define the terms displacement, amplitude, frequency, period and phase difference. • Define simple harmonic motion (SHM). • Solve problems using the defining equation for SHM.
Objectives • Apply equations for the kinematics of SHM. • Solve problems both graphically and by calculation, for acceleration, velocity and displacement during SHM.
Waves and oscillations • To oscillate means to move back and forth. • Can you give examples of oscillation?
Waves and oscillations • All things that oscillate / vibrate are ultimately linked. • Their motion can be explained using the concept of waves. • For simplicity, let us take the example of a simple pendulum.
Kinematics of SHM • Consider the following pendulum: A block of mass m attached to a spring that oscillates horizontally on a frictionless surface. • The equilibrium position is the point at which the mass rests, without external stretching or compression.
Kinematics of SHM • The force exerted by the spring is represented by the following expression: F = -kx where F is the force exerted by the spring k is the spring constant (dependent on the material of the spring) and x is the displacement of the mass m What does the negative sign signify?
Kinematics of SHM • The negative sign connotes that the restorative force of a spring is always in the opposite direction of the displacement. • When the spring is stretched and displacement x is to the right, the spring exerts a force that restores it to the left (back to equilibrium position x = 0) • When the spring is compressed and displacement is to the left, the spring exert a force to the right.
Kinematics of SHM • Consider the following simple pendulum: A mass m hanging vertically from a spring with spring constant k. • Would the equilibrium position x0 be the same as the pendulum which oscillates horizontally?
Kinematics of SHM • The spring would be stretched an extra amount related to the weight of the mass: F = mg • The equilibrium point may be defined as the point where ΣF = 0 ΣF = mg – kx0 0 = mg – kx0
Kinematics of SHM A family of 200 kg steps into a 1200-kg car and the car lowers 3.0 cm. • What is the spring constant k of the car’s springs? • How much further would the car lower if the family was 300 kg?
Kinematics of SHM • 6.5 x 104 Nm-1 • 4.5 cm
Definition of SHM • When the family’s mass is 200 kg, the springs compress 3.0 cm • When half of the mass is added, i.e. the family’s mass is 300 kg, the springs compress 4.5 cm. • What do you notice?
Definition of SHM • An oscillator for which the force exerted is proportional to its displacement is called a simple harmonic oscillator. • In other words, simple harmonic motion (SHM) is a type of motion for which F = -kx holds true.
Definition of SHM Are the following oscillators simple harmonic in nature? • F = 0.5x2 • F = -2.3y • F = 8.6x • F = -40t
Definition of SHM • no • yes • no • yes Why isn’t (c) an SHO?
Periodic nature of SHM • Imagine the motion of a simple pendulum oscillating vertically. • Consider the following characteristics:
Periodic nature of SHM • Consider the following characteristics:
Periodic nature of SHM • Computer simulation
Periodic nature of SHM • Recall the graph of an SHO’s motion. • Is acceleration constant? • How would you describe the shape of the graph?
Sinusoidal nature of SHM Definition of terms
Sinusoidal nature of SHM Wave motion
Sinusoidal nature of SHM Construct the following graphs: displacement-time velocity – time acceleration – time for a pendulum starting at maximum displacement and one starting at equilibrium position.
Sinusoidal nature of SHM • SHM is said to be sinusoidal in nature. • Depending on the starting point, the relationship between certain variables (displacement, velocity, acceleration) and time can either be a sineor cosine function.
Sinusoidal nature of SHM Relationship between period T and frequency f f (in s-1 or Hz) = T (in s) = What is the relationship between period and frequency?
Sinusoidal nature of SHM Period T of SHM T = 2π
Sinusoidal nature of SHM A spider of mass 0.30 g waits in its web of negligible mass. A slight movement causes the web to vibrate with a frequency of about 15 Hz. • Estimate the value of the spring stiffness constant k for the web • At what frequency would you expect the web to vibrate if an insect of mass 0.10 g were trapped with the spider.
Sinusoidal nature of SHM • k = 2.7 N/m • f = 13 Hz
Energy of SHM • Is work done when a spring is stretched or compressed? • How is the energy stored?
Energy of SHM • When a spring is stretched or compressed, work is done and converted into the potential energy of the spring. • Elastic potential energy is given by the expression: PE = ½ kx2 Describe what happens to a spring in terms of energy as it completes one cycle.
Energy of SHM Total mechanical E = KE +PE Total mechanical E = ½ mv2 + ½ kx2 Derive expressions for total mechanical energy, E, at maximum displacement and equilibrium position.
Energy of SHM At x = A and x = -A, v = 0, therefore: E = ½ m(02) + ½ kA2 E = ½ kA2 At equilibrium point, x = 0 and v = vmax, therefore: E = ½ mvmax2 + ½ k(0)2 E = ½ mvmax2
Energy of SHM Use the conservation of mechanical energy to deduce an expression for the instantaneous velocity of an SHO (velocity v at any time) in terms of vmax, x, and A: v = ± vmax
Energy of SHM Suppose a spring oscillator is stretched to twice the amplitude (x = 2A). What happens to the: • energy of the system • maximum velocity of the oscillator • maximum acceleration of the mass
Energy of SHM • energy is quadrupled • maximum velocity is doubled • acceleration is doubled
Energy of SHM A spring stretches 0.150 m when a 0.300-kg mass is gently lowered on it. The spring is set up on a frictionless table. The mass is pulled so that the spring is stretched 0.100 m from the equilibrium point then released from rest. Determine the: • spring stiffness constant k • amplitude of horizontal oscillation A • magnitude of maximum velocity vmax • magnitude of velocity v when the mass is 0.050 m from equilibrium and • magnitude of the maximum acceleration amax of the mass
Energy of SHM • k = 19.6 N/m • A = 0.100 m • vmax = 0.808 m/s • v = 0.70 m/s • amax= 6.53 m/s2
Simple pendulum Consider this simple pendulum. Does it oscillate? Does F = - kx still apply?
Simple pendulum Derive expressions for: • displacement along the arc • the restoring force F tangent to the arc
Simple pendulum Period, simple pendulum T = 2π