10.2. Springs http://www.ck12.org
10.2 Springs
- Calculate periods, frequencies, etc. of spring systems in harmonic motion.
Students will learn to calculate periods, frequencies, etc. of spring systems in harmonic motion.
Key Equations
T=^1 f; Period is the inverse of frequency
Tspring= 2 π
√
m
k
; Period of mass m on a spring with constant k
Fs p=−kx; the force of a spring equals the spring constant multiplied by the amount the spring is stretched or
compressed from its equilibrium point. The negative sign indicates it is a restoring force (i.e. direction of the force
is opposite its displacement from equilibrium position.
Us p=^12 kx^2 ; the potential energy of a spring is equal to one half times the spring constant times the distance
squared that it is stretched or compressed from equilibrium
Guidance
- The oscillating object does not lose any energy in SHM. Friction is assumed to be zero.
- In harmonic motion there is always arestorative force,which attempts torestorethe oscillating object to its
equilibrium position. The restorative force changes during an oscillation and depends on the position of the
object. In a spring the force is given by Hooke’s Law:F=−kx - The period,T, is the amount of time needed for the harmonic motion to repeat itself, or for the object to go one
full cycle. In SHM,Tis the time it takes the object to return to its exact starting point and starting direction. - The frequency,f,is the number of cycles an object goes through in 1 second. Frequency is measured in Hertz
(Hz). 1Hz=1 cycle per sec. - The amplitude,A, is the distance from theequilibrium(or center)pointof motion to either its lowest or highest
point (end points). The amplitude, therefore, is half of the total distance covered by the oscillating object. The
amplitude can vary in harmonic motion, but is constant in SHM.
Example 1
MEDIA
Click image to the left for use the URL below.
URL: http://www.ck12.org/flx/render/embeddedobject/1836