Dispersive Wave: Difference between revisions

Latest revision as of 14:55, 4 April 2017

Since the phase velocity in one dimension is given by $c_{p}={\frac {\omega }{k}}$ and the group velocity is given by $c_{g}={\frac {\partial \omega }{\partial k}}$ , if $c_{g}=c_{p}$ , then ${\frac {\partial \omega }{\partial k}}={\frac {\omega }{k}}$ , so that $\omega =ck$ for some scalar $c$ . Note that if $c_{p}=c_{g}=c$ , then all waves, no matter their wavelength, travel at the same speed. If the dispersion relation is some other function of $k$ , waves of different wavelengths travel at different speeds, leading to dispersion.

All of this was in the case of one dimension. In multiple dimensions we must turn to the definitions ${\vec {c_{p}}}$ = ${\frac {\omega }{|{\vec {k}}|}}{\hat {k}}$ and ${\vec {c_{g}}}$ = $\nabla _{\vec {k}}\omega$ . In this case the phase and group velocities may point many more directions than along the positive or negative $k$ axis.

Revision as of 19:03, 25 May 2015 (view source) J9shaw (talk \| contribs) No edit summary ← Older edit		Latest revision as of 14:55, 4 April 2017 (view source) Fluidslab (talk \| contribs) mNo edit summary
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	Since the [~~https://belize.math.uwaterloo.ca/mediawiki/index.php/~~Glossary#Phase_Velocity phase velocity] in one dimension is given by <math>c_p=\frac{\omega}{k}</math> and the group velocity is given by <math>c_g= \frac{\partial\omega}{\partial k}</math>, if <math>c_g = c_p</math>, then <math>\frac{\partial\omega}{\partial k} = \frac{\omega}{k}</math>, so that <math>\omega = ck </math> for some scalar <math>c</math>. Note that if <math>c_p=c_g=c</math>, then all waves, no matter their wavelength, travel at the same speed. If the dispersion relation is some other function of <math>k</math>, waves of different wavelengths travel at different speeds, leading to dispersion.		Since the [[Glossary#Phase_Velocity\|phase velocity]] in one dimension is given by <math>c_p=\frac{\omega}{k}</math> and the group velocity is given by <math>c_g= \frac{\partial\omega}{\partial k}</math>, if <math>c_g = c_p</math>, then <math>\frac{\partial\omega}{\partial k} = \frac{\omega}{k}</math>, so that <math>\omega = ck </math> for some scalar <math>c</math>. Note that if <math>c_p=c_g=c</math>, then all waves, no matter their wavelength, travel at the same speed. If the dispersion relation is some other function of <math>k</math>, waves of different wavelengths travel at different speeds, leading to dispersion.

	All of this was in the case of one dimension. In multiple dimensions we must turn to the definitions <math> \vec{c_p}</math> = <math> \frac{\omega}{\|\vec{k}\|}\hat{k}</math> and <math> \vec{c_g}</math> = <math> \nabla_{\vec{k}} \omega</math>. In this case the phase and group velocities may point many more directions than along the positive or negative <math>k</math> axis.		All of this was in the case of one dimension. In multiple dimensions we must turn to the definitions <math> \vec{c_p}</math> = <math> \frac{\omega}{\|\vec{k}\|}\hat{k}</math> and <math> \vec{c_g}</math> = <math> \nabla_{\vec{k}} \omega</math>. In this case the phase and group velocities may point many more directions than along the positive or negative <math>k</math> axis.

Dispersive Wave: Difference between revisions

Latest revision as of 14:55, 4 April 2017

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