Time reversal symmetry: Difference between revisions
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'''Time reversal symmetry''' | '''Time reversal symmetry''' refers to any [[symmetry]] in which every solution to a dispersive equation comes with a counterpart which evolves backwards in time compared to the original solution, thus the original solution at time ''t'' is linked to the reversed solution at time ''-t''. While most dispersive model equations enjoy a time reversal symmetry, this symmetry manifests itself differently from equation to equation: | ||
* For [[wave equations]], the time-reversal of a solution <math>u(t,x)</math> is usually <math>u(-t,x)</math>, although for tensor-valued [[field]]s one may also have to negate certain "time components" of the field. | * For [[wave equations]], the time-reversal of a solution <math>u(t,x)</math> is usually <math>u(-t,x)</math>, although for tensor-valued [[field]]s one may also have to negate certain "time components" of the field. | ||
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* For [[Schrodinger equations]], the time-reversal of a solution <math>u(t,x)</math> is usually <math>\overline{u}(-t,x)</math>. | * For [[Schrodinger equations]], the time-reversal of a solution <math>u(t,x)</math> is usually <math>\overline{u}(-t,x)</math>. | ||
* For [[KdV-type equations]], the time reversal of a solution <math>u(t,x)</math> is usually <math>u(-t,-x)</math>. | * For [[KdV-type equations]], the time-reversal of a solution <math>u(t,x)</math> is usually <math>u(-t,-x)</math>. | ||
Time reversal symmetry shows that the forward-in-time behavior of solutions is typically very similar to the backward-in-time behavior. This in turn implies that phenomena with a preferential direction of time (such as [[dissipation]]) cannot occur; on the other hand, phenomena such as [[local smoothing]] can still occur because they are a ''tradeoff'' between two characteristics of a solution (in this case, decay is traded for regularity). Note that the general phenomenon of KdV-type equations that solitons move to the right, while radiation moves to the left, does not contradict this because the time reversal symmetry in this case also reverses left and right. | |||
[[Category:Transforms]] | [[Category:Transforms]] |
Revision as of 01:34, 15 August 2006
Time reversal symmetry refers to any symmetry in which every solution to a dispersive equation comes with a counterpart which evolves backwards in time compared to the original solution, thus the original solution at time t is linked to the reversed solution at time -t. While most dispersive model equations enjoy a time reversal symmetry, this symmetry manifests itself differently from equation to equation:
- For wave equations, the time-reversal of a solution is usually , although for tensor-valued fields one may also have to negate certain "time components" of the field.
- For Schrodinger equations, the time-reversal of a solution is usually .
- For KdV-type equations, the time-reversal of a solution is usually .
Time reversal symmetry shows that the forward-in-time behavior of solutions is typically very similar to the backward-in-time behavior. This in turn implies that phenomena with a preferential direction of time (such as dissipation) cannot occur; on the other hand, phenomena such as local smoothing can still occur because they are a tradeoff between two characteristics of a solution (in this case, decay is traded for regularity). Note that the general phenomenon of KdV-type equations that solitons move to the right, while radiation moves to the left, does not contradict this because the time reversal symmetry in this case also reverses left and right.