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