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Work in progress by scarswell3
CLAIMED BY Taraji Long Fall 2019 11/15/2019
This topic covers Gravitational Potential Energy.
This topic covers Spring Potential Energy.


==The Main Idea==
==The Main Idea==


Elastic Potential Energy is the energy stored in elastic materials due to their deformation. Often this refers to the stretching or compressing of a spring.
[[File:spring2456.png|thumb|500 px| Spring Potential Energy]]
 
Spring potential energy, also known as elastic potential energy,is the stored energy in a spring, that can potentially be converted into kinetic energy. The energy stored in the spring is due to the deformation of the spring, often from stretching and compressing. The force excreted to stretch or compress a spring is known as Hooke's law, '''F<sub>s</sub> = -k<sub>s</sub>x''', where '''F<sub>s</sub>''' is force, '''x''' is the displacement, and '''-k<sub>s</sub>''' is the spring constant. The spring constant being unique for every spring depends on factors such as material and thickness of coiled wire. If a spring is not stretched or compressed, then it is at equilibrium. At equilibrium a spring has no potential energy, assuming there is no force being applied to the spring.  
 


===A Mathematical Model===
===A Mathematical Model===
The formula for Ideal Spring Energy is
The formula for Force of a Spring:
 
'''F<sub>s</sub> = -k<sub>s</sub>x
 
The formula for Spring Potential Energy:
 
'''U<sub>s</sub> = <sup>1</sup>&frasl;<sub>2</sub>k<sub>s</sub>x<sup>2</sup>'''


'''U<sub>s</sub>=<sup>1</sup>&frasl;<sub>2</sub>k<sub>s</sub>s<sup>2</sup>'''
where:
where:
'''k<sub>s</sub>'''= spring constant
 
'''s<sup>2</sup>'''= stretch measured from the equilibrium point;
'''k<sub>s</sub>''' = spring constant
 
'''x<sup>2</sup>''' = stretch measured from the equilibrium point;
 


===A Computational Model===
===A Computational Model===
An oscillating spring can be modeled by the following:
'''An oscillating spring on the floor:'''
from __future__ import division                 
 
from visual import *
GlowScript 2.9 VPython
from visual.graph import *
display(width=600,height=600,center=vector(6,0,0),background=color.black)
scene.width=600
mbox=2 
scene.height = 760
L0 = vector(9,0,0)
ks = 1 
deltat = .01 
t = 0   
wall=box(pos=vector(0,1,0),size=vector(0.2,3,2),color=color.cyan)
floor=box(pos=vector(7.2,-0.6,0),size=vector(14,0.2,4),color=color.cyan)
box=box(pos=vector(12,0,0),size=vector(1,1,1),color=color.red)
pivot=vector(0,0,0)
spring=helix(pos=pivot,axis=box.pos-pivot,radius=0.4,constant=1,thickness=0.1,coils=20,color=color.orange)
box.p = vector(0,0,0)
while (t<50):
  rate(100)
  s = wall.pos - box.pos
  Fspring=(L0-box.pos)*(ks)
  box.p= box.p +Fspring*deltat
  box.pos = box.pos + box.p*deltat
  spring.axis = box.pos - spring.pos
  t = t+ deltat
 
[[File:spring2457.png|500 px| Oscillating Spring on Floor]]
 
Link to Simulation:
https://trinket.io/glowscript/3146b836dc
 
'''A hanging oscillating spring:'''
 
from __future__ import division                 
from visual import *
from visual.graph import *
scene.width=600
scene.height = 760
g = 9.8
mball = .2
Lo = 0.3   
ks = 12   
deltat = 1e-3
t = 0     
ceiling = box(pos=(0,0,0), size = (0.5, 0.01, 0.2))
ball = sphere(pos=(0,-0.3,0), radius=0.025, color=color.yellow)
spring = helix(pos=ceiling.pos, color=color.green, thickness=.005, coils=10, radius=0.01)
spring.axis = ball.pos - ceiling.pos
vball = vector(0.02,0,0)
ball.p = mball*vball
scene.autoscale = 0           
scene.center = vector(0,-Lo,0) 
while t < 10:         
  rate(1000)   
  L_vector = (mag(ball.pos) - Lo)* ball.pos.norm()
  Fspring = -ks * L_vector
  Fgrav = vector(0,-mball * g,0)
  Fnet = Fspring + Fgrav
  ball.p = ball.p + Fnet * deltat
  ball.pos = ball.pos + (ball.p/mball) * deltat
  spring.axis = ball.pos-ceiling.pos 
  t = t + deltat
 
[[File:Animated-mass-spring-faster.gif|200 px]]
 
'''Code to visualize a spring's motion given x and y coordinate input:'''
 
Web VPython 3.2
scene.background = color.white
ball = sphere(radius=0.03, color=color.blue)
trail = curve(color=ball.color)
origin = sphere(pos=vector(0,0,0), color=color.yellow, radius=0.015) 
spring = helix(color=color.cyan, thickness=0.006, coils=40, radius=0.015)
spring.pos = origin.pos
xplot = graph(title="x-position vs time", xtitle="time (s)", ytitle="x-position (m)")
xposcurve = gcurve(color=color.blue, width=4, label="model")
xpos2curve = gcurve(color=color.red, width=4, label="experiment")
yplot = graph(title="y-position vs time", xtitle="time (s)", ytitle="y-position (m)")
yposcurve = gcurve(color=color.blue, width=4, label="model")
ypos2curve = gcurve(color=color.red, width=4, label="experiment")
eplot = graph(title="Change in Energy vs Time", xtitle="Time (s)", ytitle="Change in Energy (J)")
dKcurve = gcurve(color=color.blue, width=4, label="deltaK")
dUgcurve = gcurve(color=color.red, width=4, label="deltaUgrav")
dUscurve = gcurve(color=color.green, width=4, label="deltaUspring")
dEcurve = gcurve(color=color.orange, width=4, label="deltaE")
ball2 = sphere(radius=0.025, color=color.red)
ball.m = 0.402
ball.pos = vector(0.55,-0.0039,0)
ball.vel = vector(0,0,0)   
X = []
Y = []
obs = read_local_file(scene.title_anchor).text;
for line in obs.split('\n'):
    if line != '':
        line = line.split(',')
        X.append(float(line[0]))
        Y.append(float(line[1]))
idx = 0 #variable used to select data from list.
cnt = 0 #variable to keep track of predictions made between each measurement
t = 0
deltat = (5.5/len(X))/20  #choose this small AND an integer multiple of the time interval between frames of experiment video
g = 9.8
g = 9.8
mball = .2
k_s = 8.87
Lo = 0.3   
L0 = 0.123
ks = 12   
L = spring.pos-ball.pos
deltat = 1e-3
Lhat = L/mag(L)
t = 0     
s = mag(L)-L0
ceiling = box(pos=(0,0,0), size = (0.5, 0.01, 0.2))
K = (1/2)*ball.m*mag(ball.vel)**2 # kinetic energy
ball = sphere(pos=(0,-0.3,0), radius=0.025, color=color.yellow)
Ug = ball.m * g * ball.pos.y  # gravitational potential energy
spring = helix(pos=ceiling.pos, color=color.green, thickness=.005, coils=10, radius=0.01)
Us = 1/2*k_s*s**2  # spring potential energy
spring.axis = ball.pos - ceiling.pos
E = K + Ug + Us   # total energy
vball = vector(0.02,0,0)
while t < 5.5:        
ball.p = mball*vball
     K_i = K
scene.autoscale = 0           
    Ug_i = Ug
scene.center = vector(0,-Lo,0)    
     Us_i = Us
while t < 10:          
     E_i = E
     rate(1000)   
     Fgrav = vector(0,-ball.m*g,0)
     L_vector = (mag(ball.pos) - Lo)* ball.pos.norm()
    Fspring = -k_s*s*Lhat
     Fspring = -ks * L_vector
     Fgrav = vector(0,-mball * g,0)
     Fnet = Fspring + Fgrav
     Fnet = Fspring + Fgrav
     ball.p = ball.p + Fnet * deltat
     ball.vel = ball.vel+(Fnet/ball.m)*deltat
     ball.pos = ball.pos + (ball.p/mball) * deltat
     ball.pos = ball.pos+ball.vel*deltat
     spring.axis = ball.pos-ceiling.pos
    L = ball.pos-spring.pos
    Lhat = L/mag(L)
    s = mag(L)-L0
     spring.axis = L
    trail.append(pos=ball.pos)
    K = (1/2)*ball.m*mag(ball.vel)**2
    deltaK = K-K_i
    Ug = ball.m*g*ball.pos.y
    deltaUg = Ug-Ug_i
    Us = 1/2*k_s*s**2
    deltaUs = Us-Us_i
    E = K + Ug + Us
    deltaE = deltaK+deltaUg+deltaUs
    dKcurve.plot(t,deltaK)      # blue
    dUgcurve.plot(t,deltaUg)    # red
    dUscurve.plot(t,deltaUs)    # green
    dEcurve.plot(t,deltaE)      # orange
    xposcurve.plot(t,ball.pos.x)
    yposcurve.plot(t,ball.pos.y)
    # Update time
     t = t + deltat
     t = t + deltat
 
    rate(1000)


==Examples==
==Examples==
Line 52: Line 173:


===Simple===
===Simple===
'''Question'''
If a spring's spring constant is 200 N/m and it is stretched 1.5 meters from rest, what is the potential spring energy?
'''Solution'''
'''k<sub>s'''= 200 N/m
'''s'''= 1.5 m
'''U<sub>s'''=(0.5)k<sub>s</sub>s<sup>2
'''U<sub>s'''= (0.5)(200 N/m)(1.5 m)<sup>2
'''U<sub>s'''= 225 J
===Middling===
===Middling===
'''Question'''
A horizontal spring with stiffness 0.6 N/m has a relaxed length of 10 cm.  A mass of 25 g is attached and you stretch the spring to a length of 20 cm.  The mass is released and moves with little friction.  What is the speed of the mass at the moment when the spring returns to its relaxed length of 10cm?
'''Solution'''
'''k<sub>s'''= 0.6 N/m
'''s'''= 0.1 m
'''U<sub>s'''=(.5)k<sub>s</sub>s<sup>2</sup> = (.5)(0.6 N/m)(0.1 m)<sup>2
'''U<sub>s''' = 0.003 J
Potential Energy is Converted into Kinetic Energy (K):
'''U<sub>s''' = K
'''U<sub>s''' =(0.5)mv<sup>2
0.003 J = (0.5)(0.025 kg)v<sup>2
'''v<sup>2''' = <sup>(0.003 J)</sup>&frasl;<sub>((0.5)(0.025 kg))</sub>
'''v<sup>2''' = 0.24 J/kg*s
'''v''' = 0.49 m/s
===Difficult===
===Difficult===
'''Question'''
A package of mass 9 kg sits on an airless asteroid with mass 8.0x10<sup>20</sup> kg and radius 8.7x10<sup>5</sup> m.  Your goal is to launch the package so that it will never come back and when it is very far away it will have a speed of 226 m/s.  You have a spring whose stiffness is 2.8x10<sup>5</sup> N/m.  How much must you compress the spring?
'''Solution'''
The initial condition for escape from the asteroid is:
K<sub>i</sub>+U<sub>i</sub>=<sup>1</sup>&frasl;<sub>2</sub>mv<sub>esc</sub><sup>2</sup> + (-G*<sup>Mm</sup>&frasl;<sub>R)</sub>=0
Potential energy of the spring equals the total energy in the system.
'''<sup>1</sup>&frasl;<sub>2</sub>k<sub>s</sub>s<sup>2</sup>'''=<sup>1</sup>&frasl;<sub>2</sub>mv<sub>esc</sub><sup>2</sup> +(-G*<sup>Mm</sup>&frasl;<sub>R</sub>)
'''s<sup>2</sup>'''= <sup>m</sup>&frasl;<sub>k<sub>s</sub></sub>(<sup>2GM</sup>&frasl;<sub>R</sub> +v<sup>2</sup>)=s<sup>2</sup>  = <sup>9</sup>&frasl;<sub>2.8x10<sup>5</sup></sub>(<sup>2G8.0x10<sup>20</sup></sup>&frasl;<sub>8.7x10<sup>5</sup></sub>+226<sup>2</sup>)
'''s<sup>2</sup>'''=5.58 m
'''s'''=2.36 m
===Graphing===
'''Energy graph'''
The energy graph of a oscillating spring continuously switches between kinetic and potential energy because springs are continuously returning to equilibrium. The following is an example of a computational model of a hanging spring with an initial force in the positive x direction. As seen below, the energies the spring contains will always equal out to zero despite each fluctuating individually.
[[File:Spring energy.jpg]]


==Connectedness==
==Connectedness==
#How is this topic connected to something that you are interested in?
 
#How is it connected to your major?
Because springs are all around us, from Slinkies to parts in automobiles, spring potential energy is useful in everyday life. One example of this is a trampoline.  Without potential spring energy to allow for bounce, a trampoline would simply be a boring stretch of fabric.  Spring potential is also used to absorb shock in vehicles.  This allows for a smoother ride while traveling over bumps in the road. An extreme example of spring energy we commonly come across is the mechanism for garage doors. These doors contain large springs that allow them to open and close. These springs can lift an average of 400 pounds, giving them a huge amount of potential energy.
#Is there an interesting industrial application?
 
[[File:trampoline.jpg|thumb|Trampoline Potential Energy]]


==History==
==History==


Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.
 
Elastic Potential Energy stemmed from the ideas of Robert Hooke, a 17th century British physicist who studied the relationship between forces applied to springs and elasticity. Hooke’s Law, which is a principle that states that the that the force needed to extend or compress a spring by a distance is proportional to that distance.  


== See also ==
== See also ==


Are there related topics or categories in this wiki resource for the curious reader to explore?  How does this topic fit into that context?
Spring potential energy is related to [[Hooke's Law]] and [[Potential Energy]].


===Further reading===
===Further reading===


Books, Articles or other print media on this topic
http://hyperphysics.phy-astr.gsu.edu/hbase/pespr.html
 
https://www.khanacademy.org/science/ap-physics-1/ap-work-and-energy/spring-potential-energy-and-hookes-law-ap/a/spring-force-and-energy-ap1
 
https://openstax.org/books/university-physics-volume-1/pages/8-1-potential-energy-of-a-system


===External links===
===External links===


Internet resources on this topic
[http://www.physicsclassroom.com/class/energy/Lesson-1/Potential-Energy]


==References==
==References==
#http://www.universetoday.com/55027/hookes-law/
#http://www.scienceclarified.com/everyday/Real-Life-Physics-Vol-2/Oscillation-Real-life-applications.html
#http://hyperphysics.phy-astr.gsu.edu/hbase/pespr.html
#Chabay and Bruce A. Sherwood. Matter & Interactions. 4th ed.


This section contains the the references you used while writing this page
[[Category:Energy]]
 
[[Category:Which Category did you place this in?]]

Latest revision as of 04:20, 5 December 2022

CLAIMED BY Taraji Long Fall 2019 11/15/2019 This topic covers Spring Potential Energy.

The Main Idea

Spring Potential Energy

Spring potential energy, also known as elastic potential energy,is the stored energy in a spring, that can potentially be converted into kinetic energy. The energy stored in the spring is due to the deformation of the spring, often from stretching and compressing. The force excreted to stretch or compress a spring is known as Hooke's law, Fs = -ksx, where Fs is force, x is the displacement, and -ks is the spring constant. The spring constant being unique for every spring depends on factors such as material and thickness of coiled wire. If a spring is not stretched or compressed, then it is at equilibrium. At equilibrium a spring has no potential energy, assuming there is no force being applied to the spring.


A Mathematical Model

The formula for Force of a Spring:

Fs = -ksx

The formula for Spring Potential Energy:

Us = 12ksx2

where:

ks = spring constant

x2 = stretch measured from the equilibrium point;


A Computational Model

An oscillating spring on the floor:

GlowScript 2.9 VPython
display(width=600,height=600,center=vector(6,0,0),background=color.black)
mbox=2  
L0 = vector(9,0,0) 
ks = 1   
deltat = .01  
t = 0    
wall=box(pos=vector(0,1,0),size=vector(0.2,3,2),color=color.cyan)
floor=box(pos=vector(7.2,-0.6,0),size=vector(14,0.2,4),color=color.cyan)
box=box(pos=vector(12,0,0),size=vector(1,1,1),color=color.red)
pivot=vector(0,0,0)
spring=helix(pos=pivot,axis=box.pos-pivot,radius=0.4,constant=1,thickness=0.1,coils=20,color=color.orange)
box.p = vector(0,0,0)
while (t<50):
 rate(100)
 s = wall.pos - box.pos
 Fspring=(L0-box.pos)*(ks)
 box.p= box.p +Fspring*deltat
 box.pos = box.pos + box.p*deltat
 spring.axis = box.pos - spring.pos
 t = t+ deltat

Oscillating Spring on Floor

Link to Simulation: https://trinket.io/glowscript/3146b836dc

A hanging oscillating spring:

from __future__ import division                
from visual import *
from visual.graph import *
scene.width=600
scene.height = 760
g = 9.8
mball = .2
Lo = 0.3    
ks = 12    
deltat = 1e-3
t = 0       
ceiling = box(pos=(0,0,0), size = (0.5, 0.01, 0.2))
ball = sphere(pos=(0,-0.3,0), radius=0.025, color=color.yellow)
spring = helix(pos=ceiling.pos, color=color.green, thickness=.005, coils=10, radius=0.01)
spring.axis = ball.pos - ceiling.pos
vball = vector(0.02,0,0)
ball.p = mball*vball
scene.autoscale = 0            
scene.center = vector(0,-Lo,0)   
while t < 10:           
 rate(1000)    
 L_vector = (mag(ball.pos) - Lo)* ball.pos.norm()
 Fspring = -ks * L_vector
 Fgrav = vector(0,-mball * g,0)
 Fnet = Fspring + Fgrav
 ball.p = ball.p + Fnet * deltat
 ball.pos = ball.pos + (ball.p/mball) * deltat
 spring.axis = ball.pos-ceiling.pos  
 t = t + deltat

Code to visualize a spring's motion given x and y coordinate input:

Web VPython 3.2 scene.background = color.white ball = sphere(radius=0.03, color=color.blue) trail = curve(color=ball.color) origin = sphere(pos=vector(0,0,0), color=color.yellow, radius=0.015) spring = helix(color=color.cyan, thickness=0.006, coils=40, radius=0.015) spring.pos = origin.pos xplot = graph(title="x-position vs time", xtitle="time (s)", ytitle="x-position (m)") xposcurve = gcurve(color=color.blue, width=4, label="model") xpos2curve = gcurve(color=color.red, width=4, label="experiment") yplot = graph(title="y-position vs time", xtitle="time (s)", ytitle="y-position (m)") yposcurve = gcurve(color=color.blue, width=4, label="model") ypos2curve = gcurve(color=color.red, width=4, label="experiment") eplot = graph(title="Change in Energy vs Time", xtitle="Time (s)", ytitle="Change in Energy (J)") dKcurve = gcurve(color=color.blue, width=4, label="deltaK") dUgcurve = gcurve(color=color.red, width=4, label="deltaUgrav") dUscurve = gcurve(color=color.green, width=4, label="deltaUspring") dEcurve = gcurve(color=color.orange, width=4, label="deltaE") ball2 = sphere(radius=0.025, color=color.red) ball.m = 0.402 ball.pos = vector(0.55,-0.0039,0) ball.vel = vector(0,0,0) X = [] Y = [] obs = read_local_file(scene.title_anchor).text; for line in obs.split('\n'):

   if line != :
       line = line.split(',')
       X.append(float(line[0]))
       Y.append(float(line[1]))

idx = 0 #variable used to select data from list. cnt = 0 #variable to keep track of predictions made between each measurement t = 0 deltat = (5.5/len(X))/20 #choose this small AND an integer multiple of the time interval between frames of experiment video g = 9.8 k_s = 8.87 L0 = 0.123 L = spring.pos-ball.pos Lhat = L/mag(L) s = mag(L)-L0 K = (1/2)*ball.m*mag(ball.vel)**2 # kinetic energy Ug = ball.m * g * ball.pos.y # gravitational potential energy Us = 1/2*k_s*s**2 # spring potential energy E = K + Ug + Us # total energy while t < 5.5:

   K_i = K
   Ug_i = Ug
   Us_i = Us
   E_i = E
   Fgrav = vector(0,-ball.m*g,0)
   Fspring = -k_s*s*Lhat
   Fnet = Fspring + Fgrav
   ball.vel = ball.vel+(Fnet/ball.m)*deltat
   ball.pos = ball.pos+ball.vel*deltat
   L = ball.pos-spring.pos
   Lhat = L/mag(L)
   s = mag(L)-L0
   spring.axis = L
   trail.append(pos=ball.pos)
   K = (1/2)*ball.m*mag(ball.vel)**2
   deltaK = K-K_i
   Ug = ball.m*g*ball.pos.y
   deltaUg = Ug-Ug_i
   Us = 1/2*k_s*s**2
   deltaUs = Us-Us_i
   E = K + Ug + Us
   deltaE = deltaK+deltaUg+deltaUs
   dKcurve.plot(t,deltaK)      # blue
   dUgcurve.plot(t,deltaUg)    # red
   dUscurve.plot(t,deltaUs)    # green
   dEcurve.plot(t,deltaE)      # orange
   xposcurve.plot(t,ball.pos.x)
   yposcurve.plot(t,ball.pos.y)
   # Update time
   t = t + deltat
   rate(1000)

Examples

Be sure to show all steps in your solution and include diagrams whenever possible

Simple

Question

If a spring's spring constant is 200 N/m and it is stretched 1.5 meters from rest, what is the potential spring energy?

Solution

ks= 200 N/m

s= 1.5 m

Us=(0.5)kss2

Us= (0.5)(200 N/m)(1.5 m)2

Us= 225 J

Middling

Question

A horizontal spring with stiffness 0.6 N/m has a relaxed length of 10 cm. A mass of 25 g is attached and you stretch the spring to a length of 20 cm. The mass is released and moves with little friction. What is the speed of the mass at the moment when the spring returns to its relaxed length of 10cm?

Solution

ks= 0.6 N/m

s= 0.1 m

Us=(.5)kss2 = (.5)(0.6 N/m)(0.1 m)2

Us = 0.003 J

Potential Energy is Converted into Kinetic Energy (K):

Us = K

Us =(0.5)mv2

0.003 J = (0.5)(0.025 kg)v2

v2 = (0.003 J)((0.5)(0.025 kg))

v2 = 0.24 J/kg*s

v = 0.49 m/s

Difficult

Question

A package of mass 9 kg sits on an airless asteroid with mass 8.0x1020 kg and radius 8.7x105 m. Your goal is to launch the package so that it will never come back and when it is very far away it will have a speed of 226 m/s. You have a spring whose stiffness is 2.8x105 N/m. How much must you compress the spring?

Solution

The initial condition for escape from the asteroid is:


Ki+Ui=12mvesc2 + (-G*MmR)=0


Potential energy of the spring equals the total energy in the system.

12kss2=12mvesc2 +(-G*MmR)

s2= mks(2GMR +v2)=s2 = 92.8x105(2G8.0x10208.7x105+2262)

s2=5.58 m

s=2.36 m

Graphing

Energy graph

The energy graph of a oscillating spring continuously switches between kinetic and potential energy because springs are continuously returning to equilibrium. The following is an example of a computational model of a hanging spring with an initial force in the positive x direction. As seen below, the energies the spring contains will always equal out to zero despite each fluctuating individually.

Connectedness

Because springs are all around us, from Slinkies to parts in automobiles, spring potential energy is useful in everyday life. One example of this is a trampoline. Without potential spring energy to allow for bounce, a trampoline would simply be a boring stretch of fabric. Spring potential is also used to absorb shock in vehicles. This allows for a smoother ride while traveling over bumps in the road. An extreme example of spring energy we commonly come across is the mechanism for garage doors. These doors contain large springs that allow them to open and close. These springs can lift an average of 400 pounds, giving them a huge amount of potential energy.

Trampoline Potential Energy

History

Elastic Potential Energy stemmed from the ideas of Robert Hooke, a 17th century British physicist who studied the relationship between forces applied to springs and elasticity. Hooke’s Law, which is a principle that states that the that the force needed to extend or compress a spring by a distance is proportional to that distance.

See also

Spring potential energy is related to Hooke's Law and Potential Energy.

Further reading

http://hyperphysics.phy-astr.gsu.edu/hbase/pespr.html

https://www.khanacademy.org/science/ap-physics-1/ap-work-and-energy/spring-potential-energy-and-hookes-law-ap/a/spring-force-and-energy-ap1

https://openstax.org/books/university-physics-volume-1/pages/8-1-potential-energy-of-a-system

External links

[1]

References

  1. http://www.universetoday.com/55027/hookes-law/
  2. http://www.scienceclarified.com/everyday/Real-Life-Physics-Vol-2/Oscillation-Real-life-applications.html
  3. http://hyperphysics.phy-astr.gsu.edu/hbase/pespr.html
  4. Chabay and Bruce A. Sherwood. Matter & Interactions. 4th ed.