Simple Harmonic Motion - Pearland Independent School District
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Transcript Simple Harmonic Motion - Pearland Independent School District
Simple Harmonic
Motion
Pre-AP Physics
Pearland High School
Mr. Dunk
Simple Harmonic Motion
simple harmonic motion (SHM) –
vibration about an equilibrium position
in which a restoring force is
proportional to the displacement from
equilibrium
two common types of SHM are a
vibrating spring and an oscillating
pendulum
springs can vibrate horizontally (on a
frictionless surface) or vertically
Oscillating Spring
SHM and Oscillating Springs
in an oscillating spring, maximum
velocity (with Felastic = 0) is
experienced at the equilibrium point;
as the spring moves away from the
equilibrium point, the spring begins to
exert a force that causes the velocity
to decrease
the force exerted is maximum when
the spring is at maximum
displacement (either compressed or
stretched)
SHM and Oscillating Springs
at maximum displacement, the
velocity is zero; since the spring is
either stretched or compressed at this
point, a force is again exerted to start
the motion over again
in an ideal system, the mass-spring
system would oscillate indefinitely
SHM and Oscillating Springs
damping occurs when friction slows
the motion of the vibrating mass,
which causes the system to come to
rest after a period of time
if we observe a mass-spring system
over a short period of time, damping is
minimal and we can assume an ideal
mass-spring system
SHM and Oscillating Springs
in a mass-spring system, the spring
force is always trying to pull or push
the mass back toward equilibrium;
because of this, we call this force a
restoring force
in SHM, the restoring force is
proportional to the mass’
displacement; this results in all SHM
to be a simple back-and-forth motion
over the same path
Hooke’s Law
in 1678, Robert Hooke proposed this
simple relationship between force and
displacement; Hooke’s Law is
described as:
Felastic = -kx
where Felastic is the spring force,
k is the spring constant
x is the maximum displacement from
equilibrium
Hooke’s Law
the negative sign shows us that the force is
a restoring force, always moving the object
back to its equilibrium position
the spring constant has units of
Newtons/meter
the spring constant tells us how resistant a
spring is to being compressed or stretched
(how many Newtons of force are required to
stretch or compress the spring 1 meter)
when stretched or compressed, a spring
has potential energy
Simple Pendulum
simple pendulum – consists of a mass
(called a bob) that is attached to a
fixed string; we assume that the mass
of the bob is concentrated at a point at
the center of mass of the bob and the
mass of the string is negligible; we
also disregard friction and air
resistance
Simple Pendulum
Simple Pendulum
for small amplitude angles (less than
15°), a pendulum exhibits SHM
at maximum displacement from
equilibrium, a pendulum bob has
maximum potential energy; at
equilibrium, this PE has been
converted to KE
amplitude – the maximum
displacement from equilibrium
Period and Frequency
period (T) – the time, in seconds, to
execute one complete cycle of motion;
units are seconds per 1 cycle
frequency (f) – the number of
complete cycles of motion that occur
in one second; units are cycles per 1
second (also called hertz)
Period and Frequency
frequency is the reciprocal of period, so
the period of a simple pendulum depends
on the length of the string and the value for
free-fall acceleration (in most cases, gravity)
Period of a Simple
Pendulum
notice that only length of the string and the
value for free-fall acceleration affect the
period of the pendulum; period is
independent of the mass of the bob or the
amplitude
Period of a Mass-Spring
System
period of a mass-spring system depends on
mass and the spring constant
notice that only the mass and the spring
constant affect the period of a spring; period
is independent of amplitude (only for
springs that obey Hooke’s Law)
Comparison of a Pendulum
and an Oscillating Spring