Theorem von Noether: Difference between revisions

Revision as of 17:28, 12 September 2010

Mechanikvorlesung von Prof. Dr. E. Schöll, PhD

Der Artikel Theorem von Noether basiert auf der Vorlesungsmitschrift von Franz- Josef Schmitt des 3.Kapitels (Abschnitt 1) der Mechanikvorlesung von Prof. Dr. E. Schöll, PhD.

|}}

{{#set:Urheber=Prof. Dr. E. Schöll, PhD|Inhaltstyp=Script|Kapitel=3|Abschnitt=1}} Kategorie:Mechanik __SHOWFACTBOX__

Voraussetzung: Autonomes, das heißt, nicht explizit zeitabhängiges System mit f Freiheitsgraden und einer Lagrangefunktion

L({{q}_{1}},...,{{\dot {q}}_{1}},...,t)

Theorem ( E.Noether, 1882-1935)

Die Lagrangefunktion

L({{q}_{1}},...,{{\dot {q}}_{1}},...,t)

eines autonomen Systems sei unter der Transformation

{\bar {q}}\to {{h}^{s}}({\bar {q}})

invariant. Dabei ist s ein eindimensionaler Parameter und

{{h}^{s=0}}({\bar {q}})={\bar {q}}

die Identität.

Dann gibt es ein Integral der Bewegung

I({\bar {q}},{\dot {\bar {q}}})=\sum \limits _{i=1}^{f}{{\frac {\partial L}{\partial {{\dot {q}}_{i}}}}{{\left({\frac {d}{ds}}{{h}^{s}}({{q}_{i}})\right)}_{s=0}}}

Beweis:

Sei

{\bar {q}}={\bar {q}}(t)

eine Lösung der Lagrangegleichung. Dann ist auch

{\bar {q}}(s,t):={{h}^{s}}({\bar {q}},t)

Lösung, das heißt:

{\frac {d}{dt}}{\frac {\partial L({\bar {q}}(s,t),{\dot {\bar {q}}}(s,t))}{\partial {{\dot {q}}_{i}}}}={\frac {\partial L({\bar {q}}(s,t),{\dot {\bar {q}}}(s,t))}{\partial {{q}_{i}}}}

Invarianz der Lagrangefunktion für beliebige s:

{\begin{aligned}&{\frac {d}{ds}}L({\bar {q}}(s,t),{\dot {\bar {q}}}(s,t))=\sum \limits _{i=1}^{f}{\left({\frac {\partial L}{\partial {{q}_{i}}}}\left({\frac {d{{q}_{i}}}{ds}}\right)+{\frac {\partial L}{\partial {{\dot {q}}_{i}}}}{{\left({\frac {d{{\dot {q}}_{i}}}{ds}}\right)}_{}}\right)=}0\\&\Rightarrow {\frac {d}{dt}}I({\bar {q}},{\dot {\bar {q}}})=\sum \limits _{i=1}^{f}{{\frac {d}{dt}}\left({\frac {\partial L}{\partial {{\dot {q}}_{i}}}}{{\left({\frac {d}{ds}}{{h}^{s}}({{q}_{i}})\right)}_{s=0}}\right)=}\sum \limits _{i=1}^{f}{\left({\frac {d}{dt}}{\frac {\partial L}{\partial {{\dot {q}}_{i}}}}\left({\frac {d{{q}_{i}}}{ds}}\right)+{\frac {\partial L}{\partial {{\dot {q}}_{i}}}}{\frac {d}{dt}}{{\left({\frac {d{{q}_{i}}}{ds}}\right)}_{}}\right)}\\\end{aligned}}

Mit

{\begin{aligned}&{\frac {d}{dt}}{\frac {\partial L}{\partial {{\dot {q}}_{i}}}}={\frac {\partial L}{\partial {{q}_{i}}}}\\&{\frac {d}{dt}}\left({\frac {d{{q}_{i}}}{ds}}\right)=\left({\frac {d{{\dot {q}}_{i}}}{ds}}\right)\\\end{aligned}}

und mit Hilfe von

{\frac {d}{ds}}L({\bar {q}}(s,t),{\dot {\bar {q}}}(s,t))=\sum \limits _{i=1}^{f}{\left({\frac {\partial L}{\partial {{q}_{i}}}}\left({\frac {d{{q}_{i}}}{ds}}\right)+{\frac {\partial L}{\partial {{\dot {q}}_{i}}}}{{\left({\frac {d{{\dot {q}}_{i}}}{ds}}\right)}_{}}\right)=}0

folgt dann:

{\frac {d}{dt}}I({\bar {q}},{\dot {\bar {q}}})={\frac {d}{ds}}L=0

@@ Line 4: / Line 4: @@
-<math>L({{q}_{1}},...,{{\dot{q}}_{1}},...,t)</math>
+:<math>L({{q}_{1}},...,{{\dot{q}}_{1}},...,t)</math>
@@ Line 10: / Line 10: @@
 Die Lagrangefunktion
-<math>L({{q}_{1}},...,{{\dot{q}}_{1}},...,t)</math>
+:<math>L({{q}_{1}},...,{{\dot{q}}_{1}},...,t)</math>
 eines autonomen Systems sei unter der Transformation
-<math>\bar{q}\to {{h}^{s}}(\bar{q})</math>
+:<math>\bar{q}\to {{h}^{s}}(\bar{q})</math>
 invariant. Dabei ist s ein eindimensionaler Parameter und
-<math>{{h}^{s=0}}(\bar{q})=\bar{q}</math>
+:<math>{{h}^{s=0}}(\bar{q})=\bar{q}</math>
 die Identität.
@@ Line 22: / Line 22: @@
-<math>I(\bar{q},\dot{\bar{q}})=\sum\limits_{i=1}^{f}{\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}{{\left( \frac{d}{ds}{{h}^{s}}({{q}_{i}}) \right)}_{s=0}}}</math>
+:<math>I(\bar{q},\dot{\bar{q}})=\sum\limits_{i=1}^{f}{\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}{{\left( \frac{d}{ds}{{h}^{s}}({{q}_{i}}) \right)}_{s=0}}}</math>
@@ Line 28: / Line 28: @@
 Sei
-<math>\bar{q}=\bar{q}(t)</math>
+:<math>\bar{q}=\bar{q}(t)</math>
 eine Lösung der Lagrangegleichung. Dann ist auch
-<math>\bar{q}(s,t):={{h}^{s}}(\bar{q},t)</math>
+:<math>\bar{q}(s,t):={{h}^{s}}(\bar{q},t)</math>
 Lösung, das heißt:
-<math>\frac{d}{dt}\frac{\partial L(\bar{q}(s,t),\dot{\bar{q}}(s,t))}{\partial {{{\dot{q}}}_{i}}}=\frac{\partial L(\bar{q}(s,t),\dot{\bar{q}}(s,t))}{\partial {{q}_{i}}}</math>
+:<math>\frac{d}{dt}\frac{\partial L(\bar{q}(s,t),\dot{\bar{q}}(s,t))}{\partial {{{\dot{q}}}_{i}}}=\frac{\partial L(\bar{q}(s,t),\dot{\bar{q}}(s,t))}{\partial {{q}_{i}}}</math>
@@ Line 40: / Line 40: @@
-<math>\begin{align}
+:<math>\begin{align}
    & \frac{d}{ds}L(\bar{q}(s,t),\dot{\bar{q}}(s,t))=\sum\limits_{i=1}^{f}{\left( \frac{\partial L}{\partial {{q}_{i}}}\left( \frac{d{{q}_{i}}}{ds} \right)+\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}{{\left( \frac{d{{{\dot{q}}}_{i}}}{ds} \right)}_{{}}} \right)=}0 \\
   & \Rightarrow \frac{d}{dt}I(\bar{q},\dot{\bar{q}})=\sum\limits_{i=1}^{f}{\frac{d}{dt}\left( \frac{\partial L}{\partial {{{\dot{q}}}_{i}}}{{\left( \frac{d}{ds}{{h}^{s}}({{q}_{i}}) \right)}_{s=0}} \right)=}\sum\limits_{i=1}^{f}{\left( \frac{d}{dt}\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}\left( \frac{d{{q}_{i}}}{ds} \right)+\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}\frac{d}{dt}{{\left( \frac{d{{q}_{i}}}{ds} \right)}_{{}}} \right)} \\
@@ Line 52: / Line 52: @@
-<math>\frac{d}{ds}L(\bar{q}(s,t),\dot{\bar{q}}(s,t))=\sum\limits_{i=1}^{f}{\left( \frac{\partial L}{\partial {{q}_{i}}}\left( \frac{d{{q}_{i}}}{ds} \right)+\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}{{\left( \frac{d{{{\dot{q}}}_{i}}}{ds} \right)}_{{}}} \right)=}0</math>
+:<math>\frac{d}{ds}L(\bar{q}(s,t),\dot{\bar{q}}(s,t))=\sum\limits_{i=1}^{f}{\left( \frac{\partial L}{\partial {{q}_{i}}}\left( \frac{d{{q}_{i}}}{ds} \right)+\frac{\partial L}{\partial {{{\dot{q}}}_{i}}}{{\left( \frac{d{{{\dot{q}}}_{i}}}{ds} \right)}_{{}}} \right)=}0</math>
@@ Line 58: / Line 58: @@
-<math>\frac{d}{dt}I(\bar{q},\dot{\bar{q}})=\frac{d}{ds}L=0</math>
+:<math>\frac{d}{dt}I(\bar{q},\dot{\bar{q}})=\frac{d}{ds}L=0</math>

Theorem von Noether: Difference between revisions

Revision as of 17:28, 12 September 2010

Navigation menu

Search