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'''Claimed for editing by Elton Leander Pinto 10/29/2018'''
'''Claimed for editing by Elton Leander Pinto 10/29/2018'''


This is a type of periodic motion in which, from a physical point of view, a restorative force acts to always bring back the oscillating particle back to its equilibrium position. An example of a system exhibiting this kind of behavior includes a pendulum oscillating in a medium that provides minimal resistance to motion. However, most oscillating systems that we observe in our day-to-day life are not perfect simple harmonic oscillators. Simple harmonic motion is an approximation that ignores friction and air resistance. Although this assumption can often not be made in everyday calculations, simple harmonic motion can approximate these otherwise complicated situations, fairly well. This is because of the effect of damping on the motion of systems that reduces the amplitude of oscillation, and hence we get what is known as damped oscillations. Another interesting idea that is relevant when we talk about these systems is the concept of resonance, and how it can be exploited to bring about astonishing results. Simple harmonic motion can be used to estimate many systems including spring-mass systems and the swinging of a pendulum in certain instances which will be explained in further detail below. We will explore these ideas in the following section.  
'''Edited by Richard Udall June 2019'''
 
Simple harmonic motion is motion driven by a restorative force which acts to bring the oscillating particle back to its equilibrium position. Prototypical examples of this include a pendulum or a spring which is compressing and extending. However, most oscillating systems that we observe in our day-to-day life are not perfect simple harmonic oscillators. Simple harmonic motion is an approximation that ignores friction and air resistance. Although this is not generally true, simple harmonic motion is a decent approximation of these more complex systems. The more complex and accurate formulation which takes these forces into account is known as damped harmonic motion, and will be considered further in the page [[Iterative Prediction of Spring-Mass System]].  


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


Simple harmonic motion is a periodic motion, a motion that is repeated over some time interval. This periodic motion has a restoring force, a force that is always working to return the system to equilibrium position, that is proportional and opposite to displacement. Due to this as the system gets farther from equilibrium position the larger the force is to return it to equilibrium position. When no friction or air resistance is present the system will continue to oscillate as the restoring force decreases as the object gets closer to equilibrium position until the force reaches zero, but at which point the particle continues due to its initial momentum until passes equilibrium position. Then the restoring forces increases in the opposite direction until the momentum is changed enough to change the direction of the particle and the process repeats. A common example of simple harmonic motion is an undamped spring-mass system, or one that does not proceed to rest due to friction or another dissipative force.
Simple harmonic motion is a periodic motion, a motion that is repeated over some time interval. This periodic motion has a restoring force, which is a force which attempts to restore the system to its equilibrium position, and which is proportional and opposite in direction to displacement. Thus, the further the system is from its equilibrium position, the larger the force which acts to return it to equilibrium position. As the object gets closer to equilibrium position, the force decreases until is magnitude reaches zero. At the equilibrium, the particle has no forces acting upon it, but it now has a large amount of momentum, and so it passes the equilibrium point going in the opposite direction. As moves in the opposite direction from the equilibrium, the restoring forces increases in the opposite direction until the momentum reaches zero, after which the particle begins moving back towards the equilibrium. This process repeats, which leads to the periodic motion characteristic of the system. Common examples of simple harmonic motion include an undamped spring-mass system, and a pendulum swinging back and forth (in the idealized case where it does not slow down).
 
[[Image:SHM.png]]


[[File:Simple Harmonic Motion Orbit.gif|thumb|Simple Harmonic Motion Orbit]]
===A Mathematical Model===
===A Mathematical Model===


We can describe simple harmonic motion from a mathematical point of view very effectively.  
Simple harmonic motion occurs very frequently in our treatment of physical systems, and is a useful approximation for many because it is often reasonably accurate, and because we have the tools to describe it exactly. We may consider the example of the spring (see the figure) to arrive at a general equation for simple harmonic motion, and tweak its parameters to obtain an equation that is well suited to describe the oscillatory motion of spring-mass systems. If we are to pull the mass a tad bit away from its equilibrium position and then let go, we see that the spring-mass system seems to undergo some kind of periodic motion. To find a mathematical representation for such a motion, we may draw an analogy between this behavior and the mathematics at our disposal.
After a fixed period of time, we will find the system returns to its original state. Use of terminology such as period should remind one of precalculus, and specifically of the sinusoidal functions sine and cosine. Let us suppose then that the position can be described by a cosine function (we choose cosine instead of sine by convention, since in other methods of derivation it is more convenient to choose one over the other). We also know from observing the motion of the object that its position depends upon the frequency and amplitude of oscillations. Hopefully you remember how to parameterize a circle: we define <math> x = R\cos(t) </math> and <math> y = R \sin(t)  </math>, where <math> R </math> is the radius, and we take <math> t </math> from 0 to <math> 2\pi </math>. However, we could just as easily assume that <math> t </math> keeps going past <math> 2\pi </math>, or that it takes on negative values, since it will stay on the circle; we just know that it will trace out a circle over a period of <math> 2\pi </math>. By this same token, we can also choose to give <math> t </math> a coefficient, writing the equations as <math> x = R\cos(2\pi t) </math> and <math> y = R\sin(2\pi t)</math>. Then the circle will be traced out as <math> t </math> goes from 0 to 1. If we were to make the coefficient <math> \pi </math> instead, then <math> t </math> would go from 0 to 2. Thus its period would be twice as large. All of this guides how we will now write out the equation for a spring. We know that the period will affect the argument inside the cosine, and the distance it travels will be determined by the coefficient outside. Calling the maximum distance the system will extend the amplitude, <math> A </math>, and calling the inverse of the period the frequency, <math> f </math>, we have the generic equation


Let us use the example of the spring (see fig) to arrive first at a general equation for simple harmonic motion, and then tweak its parameters to obtain an equation that is well suited to describe the oscillatory motion of spring-mass systems.
<math>x(t) = A \cos(2\pi f t)</math>         


If we are to pull the mass a tad bit away from its equilibrium position and then let go, we see that the spring-mass system seems to undergo some kind of periodic motion. To find a mathematical representation for such a motion, let us try to find an analogy between what we see, and what mathematical functions we have at our disposition.
By further convention, we'll rewrite this in terms of angular frequency <math> \omega = 2 \pi f </math>, giving


The motion of the spring-mass system *repeats* itself after a *fixed interval* of time. Which mathematical function spits out the same values after a certain *period* of values? It is either the sine or the cosine function.
<math> x(t) = A \cos(\omega t) </math>


We can now see that there must be either a sine or a cosine function in our final expression that provides the position of the mass as a function of time.
We may also generalize this to assume that it does not start at maximum extension, by introducing a phase factor <math> \phi </math>


We can also see from the motion of the object that its position depends upon the frequency and amplitude of oscillations.
<math>x(t) = Acos(ωt + φ)</math>


From our knowledge of trigonometry, we know that information about the frequency has to be a parameter of either the sine or the cosine function.
Now let us consider the prominent example of a Hookean spring. The force of an ideal spring-mass system can be found using <math>\vec{F}={-k}*\vec{s}</math> where <math>\vec{s}=\vec{L}-{\vec{L}_{o}}</math>. This equation stems from  Newton's Second Law <ref>https://en.wikipedia.org/wiki/Newton%27s_laws_of_motion</ref> and Hooke's Law<ref>https://en.wikipedia.org/wiki/Hooke%27s_law</ref> which is a first order linear approximation for forces acting on an elastic system, such as a spring. The solution to this differential equation is <math>x=A\cos(\omega t + \phi)</math> where <math>ω=\sqrt{k/m}</math>. Combining this equation with our knowledge of sinusoidal functions, we define the period of oscillation to be <math>T=2π/ω</math>.


The pseudo-equation that we have derived so far looks something like this:
[[Image:SimpleHarmonicOscillation.png|500px]]


<div class="toccolours mw-collapsible mw-collapsed" style="width:700px; overflow:auto;">
<div style="font-weight:bold;line-height:1.6;">Advanced: Derivation with Differential Equations</div>
<div class="mw-collapsible-content">


<math>x(t) = cos(ωt)</math>                              (analogous to <math>cos(Bx + C)</math>)
Our differential equation is given by Hooke's Law and Newton's Second Law:


where ω is the angular frequency of oscillation
<math> x''(t) = -\frac{k}{m}x(t) </math>


This is a very nice equation (it is linear with constant coefficients)<ref> http://www.feynmanlectures.caltech.edu/I_21.html </ref>, so we may solve it by creating a linear combination of two known solutions<ref> http://tutorial.math.lamar.edu/Classes/DE/ComplexRoots.aspx </ref>. As it happens, we know two functions that can solve this equation: <math>x_1(t) = a\cos(\omega t) </math> and <math> x_2 (t) = b\sin(\omega t)</math>, where <math> \omega^2 = k/m </math>, so that a double derivative gives <math> x_1''(t) = -a \omega^2 \cos(\omega t) = - \frac{k}{m} x_1(t) </math>, and etc. for <math> x_2 </math>. Then any solution may be written as


We can very clearly see that the maximum displacement of the object away from the equilibrium position depends upon the amplitude of oscillation. Using this fact, we now get our equation for the position of an object relative to the equilibrium position as a function of time:
<math> x(t) = a \cos(\omega t) + b\sin(\omega t) </math>


Now, to make this a convenient form, lets call <math> A = \sqrt{a^2 + b^2} </math>, and pull it out, giving


<math>x(t) = A cos(ωt)</math>
<math> x(t) = A\biggr{(} \frac{a}{A} \cos(\omega t) + \frac{b}{A}\sin(\omega t) \biggr{)} </math>


By construction, these fractions look a lot like the definition of cosine and sine from trigonometry, and so we call them these respectively. Now, we can use<ref> http://www.sosmath.com/trig/Trig5/trig5/trig5.html </ref> to reduce this to


If your system doesn't start its motion from either the equilibrium position or a position of maximum displacement, then we need to add another factor to our equation to account for this. This is known as the phase difference (phase constant or phase angle) φ.
<math> x(t) = A \cos(\omega t + \phi) </math>


Now, we want to determine the constants. If the initial velocity is zero, this is easy: <math> A = x_i </math> and <math> \phi = 0 </math>. Otherwise, we will need to use the initial value conditions:


<math>x(t) = Acos(ωt + φ)</math>
<math> x(0) = A \cos(\phi) </math>


<math> x'(0) = A\omega \sin(\phi) </math>


Now that we understand how we can express simple harmonic motion mathematically, let us extend this concept and apply it to understand a spring-mass system, thereby obtaining an analytical solution for the position, angular frequency, and time period for the ideal case.
Taking a ratio of these two and solving for <math> \phi </math> will lead to


<math> \phi = \arctan\biggr{(}\frac{x'(0)}{\omega x(0)}\biggr{)} </math>


The force of a spring-mass system can be found using <math>\vec{F}={-K_{s}}*\vec{s}</math> where <math>\vec{s}=\vec{L}-{\vec{L}_{o}}</math>. This equation stems from  Newton's Second Law <ref>https://en.wikipedia.org/wiki/Newton%27s_laws_of_motion</ref> and Hooke's Law<ref>https://en.wikipedia.org/wiki/Hooke%27s_law</ref> which is a first order linear approximation for forces acting on an elastic system, such as a spring. The solution to this differential equation is <math>x=Acos(ωt)</math> where <math>ω=\sqrt{{K_{s}}/m}</math>. From this equation we can determine that the period for this function, or the time it takes an object to make one complete cycle of motion, to be <math>T=2π/ω</math>.
Finally, this may be substituted into either equation to solve for <math> A </math>  


[[Image:SimpleHarmonicOscillation.png|500px]]
</div></div>


===A Computational Model===
===A Computational Model===
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===Simple===
===Simple===
Problem: A spring has a restoring force of 300 N when it is stretched -.2m.  What is the spring's constant <math>{K_{s}}</math>. in N/m?  
Problem: A spring has a restoring force of <math> 300 N </math> when it is compressed <math> 0.2 m </math>.  What is the spring's constant <math>k</math> in <math>N/m</math>?  


<div class="toccolours mw-collapsible mw-collapsed" style="width:400px; overflow:auto;">
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<div class="mw-collapsible-content">


<math>F={-K_{s}}*s</math>
Hooke's law gives
 
<math>\vec{F}=-k\vec{s}</math>
 
So rearranging gives
 
<math>-k=\frac{\vec{F}}{\vec{s}}</math>


<math>{-K_{s}}=F/s</math>
Orienting the direction of extension as the positive direction, we have <math> \vec{F} = 300 N </math> and <math> \vec{s} = -0.2 m </math>


<math>{-K_{s}}=300N/-.2m</math>
<math>-k=\frac{300 N}{-.2 m}</math>


<math>{K_{s}}=1500N/m</math>
<math>k=\frac{1500N}{m}</math>


</div></div>
</div></div>
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<div style="font-weight:bold;line-height:1.6;">Solution</div>
<div style="font-weight:bold;line-height:1.6;">Solution</div>
<div class="mw-collapsible-content">
<div class="mw-collapsible-content">
<math>T=2π/ω</math> or <math>T=2π√(m/{K_{s}})</math>


<math>{K_{s}}=15N/m)</math> and <math>m=30kg</math>
First, we have by definition that


<math>T=2π√(30kg/15N/m)</math>
<math>T=\frac{2\pi}{\omega}</math>  


<math>T=8.88 seconds</math>
and using the formula for <math> \omega </math> gives
 
<math>T=2\pi\sqrt{\frac{m}{k}}</math>
 
<math>k=15 (N/m)</math> and <math>m=30kg</math>
 
<math>T=2\pi \sqrt{\frac{30 kg}{15(N/m)}}</math>
 
<math>T=8.88 s</math>


</div></div>
</div></div>
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<div style="font-weight:bold;line-height:1.6;">Solution</div>
<div style="font-weight:bold;line-height:1.6;">Solution</div>
<div class="mw-collapsible-content">
<div class="mw-collapsible-content">
<math>x=Acos(ωt)</math>
<math>x=A\cos(\omega t)</math>


<math>x/A=cos(√({K_{s}}/m)t)</math>
<math>\frac{x}{A}=\cos\biggr{(}\sqrt{\frac{k}{m}}t\biggr{)}</math>


<math>1/2=cos((18N/m/2kg)t)</math>
<math>1/2=\cos\biggr{(}\sqrt{\frac{18 (N/m)}{2 kg}}t\biggr{)}</math>


<math>cos^{-1}(1/2)=3t</math>
<math>\arccos(1/2)=3(Hz) \cdot t</math>


<math>t=.35seconds</math>
<math>t=.35 s</math>
</div></div>
</div></div>
==Damping==
We know from our observations of say a pendulum swinging or a spring bobbing that it's periodic motion eventually dies out. This is due to the dissipative forces prevalent in nature (air resistance and viscous drag ) that dissipate the potential and kinetic energies of the system (spring+mass) to the surroundings (everything outside our chosen system ) into other forms of energy (heat, sound, etc.). When this happens, we say that the system is executing damped oscillations.
It takes some hairy math to arrive at an approximate analytical solution for the above case. Instead of doing that, however, it is much easier for us to encode the presence of dissipative forces if we were to carry out numerical integration using an iterative process.
Whenever we calculate the net force on the mass during the iterative process, all we have to do now is add a force that is representative of any of the dissipative forces. If we are dealing with air resistance, then we can use the equation
<math>\vec{F} = -0.5CAρv^2\hat{v}</math>
Else, we can use this equation
<math>\vec{F} = -b\vec{v}</math>
where b is the damping constant
[[Image:Screen Shot 2018-11-20 at 12.05.27 PM.png]]


==Connectedness==
==Connectedness==
[A student should expand upon this]


One interesting application of simple harmonic motion is its ability to approximate the interatomic vibration of molecules which I find very interesting as an Earth and Atmospheric Science major, trying to better understand our environment and how the molecules it is made up of interact.  I have always been very intrigued by the composition and interactions of molecules and this approximations brings me another step closer to understanding how our world works. An interesting industrial application of simple harmonic motion is  its approximation of a car running on worn down shock absorbers.
One interesting application of simple harmonic motion is its ability to approximate the interatomic vibration of molecules which I find very interesting as an Earth and Atmospheric Science major, trying to better understand our environment and how the molecules it is made up of interact.  I have always been very intrigued by the composition and interactions of molecules and this approximations brings me another step closer to understanding how our world works. An interesting industrial application of simple harmonic motion is  its approximation of a car running on worn down shock absorbers.
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==History==
==History==


Thomas Hooke, an English scientist, created Hooke's Law in 1660 while working on his invention the watch-spring. In the 1660s Hooke gained the title of curator of the Royal Society where he led top experiments for the society. The watch-spring Hooke was working on was one of the first capable of determining longitude at sea by using a spring in simple harmonic motion which has a tendency resist disturbances such as the shakes that could occur while at sea.
Thomas Hooke, an English scientist, discovered what is now known as Hooke's Law in 1660 while working on the springs of watches.<ref> https://www.britannica.com/science/Hookes-law </ref> A remarkable physicist, Hooke was also a pioneer in optics, astronomy, and fluid mechanics. He supported a theory of evolution nearly two hundred years before Darwin (although he did not know about the principle of natural selection), devised the inverse square law which Newton adapted, and accurately described air as individual particles separated by large distances.<ref> https://www.britannica.com/biography/Robert-Hooke </ref> Harmonic motion is thus named because of its connection to music: instruments vibrate, and in doing so produce the sounds we perceive as music.<ref> https://www.britannica.com/science/simple-harmonic-motion </ref> The Fourier series allows for the expression of ''any'' periodic function in terms of sinusoids, meaning that a huge variety of phenomena in physics may be decomposed into simple harmonic motion. Furthermore, for reasons discussed in reference 8, harmonic oscillators are a strong approximation of many systems near equilibrium. The corresponding quantum harmonic oscillator is similarly useful in quantum mechanics. <ref> https://phys.libretexts.org/Bookshelves/University_Physics/Book%3A_University_Physics_(OpenStax)/Map%3A_University_Physics_III_-_Optics_and_Modern_Physics_(OpenStax)/7%3A_Quantum_Mechanics/7.5%3A_The_Quantum_Harmonic_Oscillator </ref>.


== See also ==
== See also ==
 
*[[Fundamentals of Iterative Prediction with Varying Force]]
[[Hooke's Law]]
*[[Iterative Prediction of Spring-Mass System]]
*[[Two Dimensional Harmonic Motion]]


===External links===
===External links===
https://www.khanacademy.org/science/physics/oscillatory-motion/harmonic-motion/v/introduction-to-harmonic-motion
*https://www.khanacademy.org/science/physics/oscillatory-motion/harmonic-motion/v/introduction-to-harmonic-motion
 
*http://hyperphysics.phy-astr.gsu.edu/hbase/shm.html
http://hyperphysics.phy-astr.gsu.edu/hbase/shm.html
*https://en.wikibooks.org/wiki/A-level_Physics_(Advancing_Physics)/Simple_Harmonic_Motion/Mathematical_Derivation
*http://www.feynmanlectures.caltech.edu/I_21.html


https://en.wikibooks.org/wiki/A-level_Physics_(Advancing_Physics)/Simple_Harmonic_Motion/Mathematical_Derivation
===Further Reading===
*Matter and Interactions, 4th Edition


==References==
==References==
<references/>
<references/>

Latest revision as of 15:24, 29 July 2019

Claimed for editing by Elton Leander Pinto 10/29/2018

Edited by Richard Udall June 2019

Simple harmonic motion is motion driven by a restorative force which acts to bring the oscillating particle back to its equilibrium position. Prototypical examples of this include a pendulum or a spring which is compressing and extending. However, most oscillating systems that we observe in our day-to-day life are not perfect simple harmonic oscillators. Simple harmonic motion is an approximation that ignores friction and air resistance. Although this is not generally true, simple harmonic motion is a decent approximation of these more complex systems. The more complex and accurate formulation which takes these forces into account is known as damped harmonic motion, and will be considered further in the page Iterative Prediction of Spring-Mass System.

The Main Idea

Simple harmonic motion is a periodic motion, a motion that is repeated over some time interval. This periodic motion has a restoring force, which is a force which attempts to restore the system to its equilibrium position, and which is proportional and opposite in direction to displacement. Thus, the further the system is from its equilibrium position, the larger the force which acts to return it to equilibrium position. As the object gets closer to equilibrium position, the force decreases until is magnitude reaches zero. At the equilibrium, the particle has no forces acting upon it, but it now has a large amount of momentum, and so it passes the equilibrium point going in the opposite direction. As moves in the opposite direction from the equilibrium, the restoring forces increases in the opposite direction until the momentum reaches zero, after which the particle begins moving back towards the equilibrium. This process repeats, which leads to the periodic motion characteristic of the system. Common examples of simple harmonic motion include an undamped spring-mass system, and a pendulum swinging back and forth (in the idealized case where it does not slow down).

Simple Harmonic Motion Orbit

A Mathematical Model

Simple harmonic motion occurs very frequently in our treatment of physical systems, and is a useful approximation for many because it is often reasonably accurate, and because we have the tools to describe it exactly. We may consider the example of the spring (see the figure) to arrive at a general equation for simple harmonic motion, and tweak its parameters to obtain an equation that is well suited to describe the oscillatory motion of spring-mass systems. If we are to pull the mass a tad bit away from its equilibrium position and then let go, we see that the spring-mass system seems to undergo some kind of periodic motion. To find a mathematical representation for such a motion, we may draw an analogy between this behavior and the mathematics at our disposal. After a fixed period of time, we will find the system returns to its original state. Use of terminology such as period should remind one of precalculus, and specifically of the sinusoidal functions sine and cosine. Let us suppose then that the position can be described by a cosine function (we choose cosine instead of sine by convention, since in other methods of derivation it is more convenient to choose one over the other). We also know from observing the motion of the object that its position depends upon the frequency and amplitude of oscillations. Hopefully you remember how to parameterize a circle: we define [math]\displaystyle{ x = R\cos(t) }[/math] and [math]\displaystyle{ y = R \sin(t) }[/math], where [math]\displaystyle{ R }[/math] is the radius, and we take [math]\displaystyle{ t }[/math] from 0 to [math]\displaystyle{ 2\pi }[/math]. However, we could just as easily assume that [math]\displaystyle{ t }[/math] keeps going past [math]\displaystyle{ 2\pi }[/math], or that it takes on negative values, since it will stay on the circle; we just know that it will trace out a circle over a period of [math]\displaystyle{ 2\pi }[/math]. By this same token, we can also choose to give [math]\displaystyle{ t }[/math] a coefficient, writing the equations as [math]\displaystyle{ x = R\cos(2\pi t) }[/math] and [math]\displaystyle{ y = R\sin(2\pi t) }[/math]. Then the circle will be traced out as [math]\displaystyle{ t }[/math] goes from 0 to 1. If we were to make the coefficient [math]\displaystyle{ \pi }[/math] instead, then [math]\displaystyle{ t }[/math] would go from 0 to 2. Thus its period would be twice as large. All of this guides how we will now write out the equation for a spring. We know that the period will affect the argument inside the cosine, and the distance it travels will be determined by the coefficient outside. Calling the maximum distance the system will extend the amplitude, [math]\displaystyle{ A }[/math], and calling the inverse of the period the frequency, [math]\displaystyle{ f }[/math], we have the generic equation

[math]\displaystyle{ x(t) = A \cos(2\pi f t) }[/math]

By further convention, we'll rewrite this in terms of angular frequency [math]\displaystyle{ \omega = 2 \pi f }[/math], giving

[math]\displaystyle{ x(t) = A \cos(\omega t) }[/math]

We may also generalize this to assume that it does not start at maximum extension, by introducing a phase factor [math]\displaystyle{ \phi }[/math]

[math]\displaystyle{ x(t) = Acos(ωt + φ) }[/math]

Now let us consider the prominent example of a Hookean spring. The force of an ideal spring-mass system can be found using [math]\displaystyle{ \vec{F}={-k}*\vec{s} }[/math] where [math]\displaystyle{ \vec{s}=\vec{L}-{\vec{L}_{o}} }[/math]. This equation stems from Newton's Second Law [1] and Hooke's Law[2] which is a first order linear approximation for forces acting on an elastic system, such as a spring. The solution to this differential equation is [math]\displaystyle{ x=A\cos(\omega t + \phi) }[/math] where [math]\displaystyle{ ω=\sqrt{k/m} }[/math]. Combining this equation with our knowledge of sinusoidal functions, we define the period of oscillation to be [math]\displaystyle{ T=2π/ω }[/math].

Advanced: Derivation with Differential Equations

Our differential equation is given by Hooke's Law and Newton's Second Law:

[math]\displaystyle{ x''(t) = -\frac{k}{m}x(t) }[/math]

This is a very nice equation (it is linear with constant coefficients)[3], so we may solve it by creating a linear combination of two known solutions[4]. As it happens, we know two functions that can solve this equation: [math]\displaystyle{ x_1(t) = a\cos(\omega t) }[/math] and [math]\displaystyle{ x_2 (t) = b\sin(\omega t) }[/math], where [math]\displaystyle{ \omega^2 = k/m }[/math], so that a double derivative gives [math]\displaystyle{ x_1''(t) = -a \omega^2 \cos(\omega t) = - \frac{k}{m} x_1(t) }[/math], and etc. for [math]\displaystyle{ x_2 }[/math]. Then any solution may be written as

[math]\displaystyle{ x(t) = a \cos(\omega t) + b\sin(\omega t) }[/math]

Now, to make this a convenient form, lets call [math]\displaystyle{ A = \sqrt{a^2 + b^2} }[/math], and pull it out, giving

[math]\displaystyle{ x(t) = A\biggr{(} \frac{a}{A} \cos(\omega t) + \frac{b}{A}\sin(\omega t) \biggr{)} }[/math]

By construction, these fractions look a lot like the definition of cosine and sine from trigonometry, and so we call them these respectively. Now, we can use[5] to reduce this to

[math]\displaystyle{ x(t) = A \cos(\omega t + \phi) }[/math]

Now, we want to determine the constants. If the initial velocity is zero, this is easy: [math]\displaystyle{ A = x_i }[/math] and [math]\displaystyle{ \phi = 0 }[/math]. Otherwise, we will need to use the initial value conditions:

[math]\displaystyle{ x(0) = A \cos(\phi) }[/math]

[math]\displaystyle{ x'(0) = A\omega \sin(\phi) }[/math]

Taking a ratio of these two and solving for [math]\displaystyle{ \phi }[/math] will lead to

[math]\displaystyle{ \phi = \arctan\biggr{(}\frac{x'(0)}{\omega x(0)}\biggr{)} }[/math]

Finally, this may be substituted into either equation to solve for [math]\displaystyle{ A }[/math]

A Computational Model

Simple harmonic motion in vPython uses glowscript to implement a varying force iterative motion predictor, while this has uses numpy to do the same (here the cell with simp_harm_func is the one we wish to look at). For a detailed description of how varying force computational methods work, see Fundamentals of Iterative Prediction with Varying Force. The important distinction of simple harmonic motion is that it is defined by the force function

[math]\displaystyle{ F(t,x,v) = -kx }[/math]

Where by convention we have [math]\displaystyle{ k \gt 0 }[/math].

Examples

Simple

Problem: A spring has a restoring force of [math]\displaystyle{ 300 N }[/math] when it is compressed [math]\displaystyle{ 0.2 m }[/math]. What is the spring's constant [math]\displaystyle{ k }[/math] in [math]\displaystyle{ N/m }[/math]?

Solution

Hooke's law gives

[math]\displaystyle{ \vec{F}=-k\vec{s} }[/math]

So rearranging gives

[math]\displaystyle{ -k=\frac{\vec{F}}{\vec{s}} }[/math]

Orienting the direction of extension as the positive direction, we have [math]\displaystyle{ \vec{F} = 300 N }[/math] and [math]\displaystyle{ \vec{s} = -0.2 m }[/math]

[math]\displaystyle{ -k=\frac{300 N}{-.2 m} }[/math]

[math]\displaystyle{ k=\frac{1500N}{m} }[/math]

Middling

Problem: What is the oscillation period of a spiring with spring constant 15N/m with a 30 kg mass attached?

Solution

First, we have by definition that

[math]\displaystyle{ T=\frac{2\pi}{\omega} }[/math]

and using the formula for [math]\displaystyle{ \omega }[/math] gives

[math]\displaystyle{ T=2\pi\sqrt{\frac{m}{k}} }[/math]

[math]\displaystyle{ k=15 (N/m) }[/math] and [math]\displaystyle{ m=30kg }[/math]

[math]\displaystyle{ T=2\pi \sqrt{\frac{30 kg}{15(N/m)}} }[/math]

[math]\displaystyle{ T=8.88 s }[/math]

Difficult

Problem: A spring with spring constant 18 N/m has mass of 2 kg is attached to it. The mass is then displaced to x = 2 . How much time does it take for the block to travel to the point x = 1?

Solution:

Solution

[math]\displaystyle{ x=A\cos(\omega t) }[/math]

[math]\displaystyle{ \frac{x}{A}=\cos\biggr{(}\sqrt{\frac{k}{m}}t\biggr{)} }[/math]

[math]\displaystyle{ 1/2=\cos\biggr{(}\sqrt{\frac{18 (N/m)}{2 kg}}t\biggr{)} }[/math]

[math]\displaystyle{ \arccos(1/2)=3(Hz) \cdot t }[/math]

[math]\displaystyle{ t=.35 s }[/math]

Connectedness

[A student should expand upon this]

One interesting application of simple harmonic motion is its ability to approximate the interatomic vibration of molecules which I find very interesting as an Earth and Atmospheric Science major, trying to better understand our environment and how the molecules it is made up of interact. I have always been very intrigued by the composition and interactions of molecules and this approximations brings me another step closer to understanding how our world works. An interesting industrial application of simple harmonic motion is its approximation of a car running on worn down shock absorbers.

History

Thomas Hooke, an English scientist, discovered what is now known as Hooke's Law in 1660 while working on the springs of watches.[6] A remarkable physicist, Hooke was also a pioneer in optics, astronomy, and fluid mechanics. He supported a theory of evolution nearly two hundred years before Darwin (although he did not know about the principle of natural selection), devised the inverse square law which Newton adapted, and accurately described air as individual particles separated by large distances.[7] Harmonic motion is thus named because of its connection to music: instruments vibrate, and in doing so produce the sounds we perceive as music.[8] The Fourier series allows for the expression of any periodic function in terms of sinusoids, meaning that a huge variety of phenomena in physics may be decomposed into simple harmonic motion. Furthermore, for reasons discussed in reference 8, harmonic oscillators are a strong approximation of many systems near equilibrium. The corresponding quantum harmonic oscillator is similarly useful in quantum mechanics. [9].

See also

External links

Further Reading

  • Matter and Interactions, 4th Edition

References