https://wikimd.com/index.php?action=history&feed=atom&title=Simple_harmonic_motionSimple harmonic motion - Revision history2026-04-06T17:28:18ZRevision history for this page on the wikiMediaWiki 1.44.2https://wikimd.com/index.php?title=Simple_harmonic_motion&diff=5648074&oldid=prevPrab: CSV import2024-04-22T07:49:22Z<p>CSV import</p>
<p><b>New page</b></p><div>[[File:Simple_Harmonic_Motion_Orbit.gif|Simple Harmonic Motion Orbit|thumb]] [[Image:Animated-mass-spring.gif|Animated-mass-spring|thumb|left]] [[File:ลูกตุ้มธรรมชาติ.gif|ลูกตุ้มธรรมชาติ|thumb|left]] [[File:Scotch_yoke_animation.gif|Scotch yoke animation|thumb]] '''Simple Harmonic Motion''' (SHM) is a type of periodic motion or oscillation motion where the restoring force is directly proportional to the displacement and acts in the direction opposite to that of displacement. SHM can serve as a mathematical model for a variety of motions, such as the oscillation of a spring or the pendulum of a clock.<br />
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==Definition==<br />
In simple harmonic motion, the displacement ''x'' of the particle from the equilibrium position is described by the equation:<br />
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\[ x(t) = A \cos(\omega t + \phi) \]<br />
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where:<br />
* ''A'' is the amplitude of the oscillation - the maximum displacement from the equilibrium position.<br />
* ''\(\omega\)'' is the angular frequency of the oscillation, which determines how many oscillations occur in a unit of time.<br />
* ''t'' is the time.<br />
* ''\(\phi\)'' is the phase of the oscillation at ''t'' = 0.<br />
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The velocity ''v'' and acceleration ''a'' of the particle can be derived from the displacement as:<br />
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\[ v(t) = -A\omega \sin(\omega t + \phi) \]<br />
\[ a(t) = -A\omega^2 \cos(\omega t + \phi) \]<br />
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The acceleration is thus also directly proportional to the displacement but in the opposite direction, which characterizes SHM.<br />
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==Characteristics==<br />
* '''Periodic Motion''': SHM repeats itself in equal intervals of time known as the period (''T'').<br />
* '''Restoring Force''': The force that brings the system back to its equilibrium position is always directed opposite to the displacement.<br />
* '''Energy Conservation''': In SHM, energy is conserved, oscillating between kinetic energy and potential energy.<br />
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==Examples==<br />
* A mass attached to a spring on a frictionless surface.<br />
* A simple pendulum, for small angles of displacement.<br />
* The motion of a diatomic molecule.<br />
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==Mathematical Analysis==<br />
The period ''T'' of simple harmonic motion is given by:<br />
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\[ T = 2\pi\sqrt{\frac{m}{k}} \]<br />
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where ''m'' is the mass of the oscillating object and ''k'' is the spring constant for a mass-spring system, or the gravitational constant over the length of the pendulum in the case of a simple pendulum.<br />
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The frequency ''f'' is the reciprocal of the period (''T''):<br />
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\[ f = \frac{1}{T} \]<br />
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==Applications==<br />
SHM is foundational in the study of [[waves]] and [[vibrations]], and has applications in various fields including [[engineering]], [[physics]], and even [[music]]. Understanding SHM is crucial for the design of structures that must withstand vibrational forces, such as buildings in earthquake-prone areas, and for the analysis of sound waves.<br />
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==See Also==<br />
* [[Harmonic oscillator]]<br />
* [[Pendulum]]<br />
* [[Wave motion]]<br />
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[[Category:Physics]]<br />
[[Category:Oscillation]]<br />
[[Category:Mechanics]]<br />
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