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Composition Setup

Excerpt
hiddentrue

System: One point particle constrained to move in one dimension. — Interactions: The particle must experience a force (or torque) that attempts to restore it to equilibrium and is directly proportional to its displacement from that equilibrium.

Introduction to the Model

Description and Assumptions

This model applies to position of a single point particle, or to the angular position of a rigid body, which is constrained to one dimension and experiences a restoring force that is linearly proportional to its displacement from an equilibrium position. This form for the force or torque implies that the equation of motion for the point particle or rigid body will have the form:

Latex
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{td:align=center|bgcolor=#F2F2F2}*[Model Hierarchy]*
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h2. Description and Assumptions

{excerpt}This model applies to a single [point particle] constrained to move in one dimension whose position is a sinusoidal function of time.  Simple harmonic motion is sometimes abbreviated SHM.{excerpt}


h2. Problem Cues

Any object that experiences a _linear_ restoring force or torque so that the equation of motion takes the form 

{latex}\begin{large}\[ a = \frac{d^{2}x}{dt^{2}} = - \omega^omega_{\rm osc}^{2}x \]\end{large}{latex}

or

{latex}

or

Latex
\begin{large}\[ \alpha = \frac{d^{2}\theta}{dt^{2}} = -\omega^\omega_{\rm osc}^{2}\theta.\] \end{large}{latex}

will experience simple harmonic motion with angular frequency ω.  The prototypical example is an object of mass _m_ attached to a spring with force constant _k_, in which case, by [Hooke's Law]:

{latex}

As a consequence of this characteristic equation, the position, velocity, and acceleration (or the angular equivalents) will each be sinusoidal functions of time. Simple harmonic motion is sometimes abbreviated SHM, or referred to as "Simple Harmonic Oscillation" (SHO).

Learning Objectives

Students will be assumed to understand this model who can:

Relevant Definitions
Section
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Latex
\begin{large}\[
a = -\frac{kx}{m
 A \equiv x_{\rm max} = \sqrt{x_{i}^{2} + \left(\frac{v_{i}}{\omega_{\rm osc}}\right)^{2}} \]\end{large}
{latex} giving simple harmonic motion with angular frequency {latex}$\sqrt{\dfrac{k}{m}}${latex}. ---- || Page Contents || | {toc:style=none|indent=10px} | ---- h2. Prerequisite Knowledge h4. Prior Models * [1-D Motion (Constant Velocity)] * [1-D Motion (Constant Acceleration)] h4. Vocabulary and Procedures * [restoring force] * [periodic motion] * [angular frequency] * [phase] ---- h2. System h4. Constituents A single [point particle|point particle] (or, for the angular version of SHM, a single [rigid body]). h4. State Variables Time (_t_), position (_x_) , velocity (_v_) and acceleration (_a_) or their angular equivalents. ---- h2. Interactions h4. Relevant Types The system must be subject to a one-dimensional restoring force (or torque) that varies linearly with the displacement (or angular displacement) from an equilibrium position. h4. Interaction Variables
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Latex
\begin{large}\[ \phi = \cos^{-1}\left(\frac{x_{i}}{A}\right) = \sin^{-1}\left(\frac{v_{i}}{\omega_{\rm osc} A}\right)\]\end{large}

S.I.M. Structure of the Model

Compatible Systems

A single point particle (or, for the angular version of SHM, a single rigid body).

Relevant Interactions

The system must be subject to a one-dimensional restoring force (or torque) that varies linearly with the displacement (or angular displacement) from a stable equilibrium position.

Laws of Change

Mathematical Representation
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borderWidth1
titleUsing Initial Time
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Section
Force (_F_) or the angular equivalent. ---- h2. Model h4. Relevant Definitions Amplitude of motion: {latex}
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bgColor#FFFFFF
titlePosition
Center
Latex
\begin{large}\[ 
A
x(t) = 
\sqrt{
x_{i
}^{2}
}\cos(\omega_{\rm osc} (t-t_{i})) + 
\left(
\frac{v_{i}}{\omega_{\rm osc}}\
right)^{2}}
sin(\omega_{\rm osc} (t-t_{i}))\]\end{large}
{latex} Phase: {latex}
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bgColor#FFFFFF
titleVelocity
Center
Latex
\begin{large}\[ 
\phi
v(t) = 
\cos^{-1}\left(\frac{x
-\omega_{\rm osc} x_{i}\sin(\omega_{\rm osc} (t-t_{i}
}{A}\right
)) 
=
+ 
\sin^{-1
v_{i}\
left
cos(\
frac{v
omega_{\rm osc} (t-t_{i}
}{\omega A}\right)
))\]\end{large}
Section
h4. Laws of Change \\ \\ {latex}
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titleAcceleration
Center
Latex
\begin{large}\[ 
x
a(t) = -\omega_{\rm osc}^{2} x_{i}\cos(\omega_{\rm osc} (t-t_{i})) 
+
- \
frac{
omega_{\rm osc} v_{i}
}{omega}
 \sin(\omega_{\rm osc} (t-t_{i}))
\]\end{
 = -\omega_{\rm osc}^{2} x(t) \]\end{large}



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large}{latex} \\ or, equivalently \\ {latex}
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titlePosition
Center
Latex
\begin{large}\[ x(t) = A\cos(\omega_{\rm osc} t + \phi)
\]\end{large}
{latex} \\ {latex}
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titleVelocity
Center
Latex
\begin{large}\[ 
\frac{dx}{dt} = v
v(t) =-A\omega_{\rm osc}\sin(\omega_{\rm osc} t + \phi)\]\end{large}
{latex}\\ \\ ---- h2. Diagrammatical Representations * Acceleration versus time graph. * Velocity versus time graph. * Position versus time graph. ---- h2. Relevant Examples None yet. ---- {search-box} \\ \\ | !copyright and waiver^copyrightnotice.png! | RELATE wiki by David E. Pritchard is licensed under a [Creative Commons Attribution-Noncommercial-Share Alike 3.0 United States License|http://creativecommons.org/licenses/by-nc-sa/3.0/us/]. |
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titleAcceleration
Center
Latex
\begin{large}\[ a(t) =-\omega_{\rm osc}^{2}A\cos(\omega_{\rm osc} t+\phi) =-\omega_{\rm osc}^{2} x(t)\]\end{large}
Diagrammatic Representations

Image Added

Click here for a Mathematica Player application illustrating these representations using phase.

Image Added

Click here to download the (free) Mathematica Player from Wolfram Research

Relevant Examples

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idPend
Examples involving Pendulums

...

Cloak
idPend
AND50falsetrueexample_problem,SHM,pendulum Pend
Spr Examples involving Springs
Spr AND50falsetrueexample_problem,SHM,spring Spr
RelEx All Examples involving this Model
RelEx AND50falsetrueexample_problem,SHM