Schur orthogonality relations: Difference between revisions

Revision as of 09:27, 8 November 2013

Generating functions which arise in Hamiltonian mechanics are quite different from generating functions in mathematics. In physics, a generating function acts as a bridge between two sets of canonical variables when performing a canonical transformation.

Details

There are four basic generating functions, summarized by the following table:

Generating Function	Its Derivatives
$F = F_{1} (q, Q, t)$	$p = \frac{\partial F_{1}}{\partial q}$ and $P = - \frac{\partial F_{1}}{\partial Q}$
$F = F_{2} (q, P, t) - Q P$	$p = \frac{\partial F_{2}}{\partial q}$ and $Q = \frac{\partial F_{2}}{\partial P}$
$F = F_{3} (p, Q, t) + q p$	$q = - \frac{\partial F_{3}}{\partial p}$ and $P = - \frac{\partial F_{3}}{\partial Q}$
$F = F_{4} (p, P, t) + q p - Q P$	$q = - \frac{\partial F_{4}}{\partial p}$ and $Q = \frac{\partial F_{4}}{\partial P}$

Example

Sometimes a given Hamiltonian can be turned into one that looks like the harmonic oscillator Hamiltonian, which is

H = a P^{2} + b Q^{2} .

For example, with the Hamiltonian

H = \frac{1}{2 q^{2}} + \frac{p^{2} q^{4}}{2},

where p is the generalized momentum and q is the generalized coordinate, a good canonical transformation to choose would be

Template:NumBlk

This turns the Hamiltonian into

H = \frac{Q^{2}}{2} + \frac{P^{2}}{2},

which is in the form of the harmonic oscillator Hamiltonian.

The generating function F for this transformation is of the third kind,

F = F_{3} (p, Q) .

To find F explicitly, use the equation for its derivative from the table above,

P = - \frac{\partial F_{3}}{\partial Q},

and substitute the expression for P from equation (Template:EquationNote), expressed in terms of p and Q:

\frac{p}{Q^{2}} = - \frac{\partial F_{3}}{\partial Q}

Integrating this with respect to Q results in an equation for the generating function of the transformation given by equation (Template:EquationNote):

F_{3} (p, Q) = \frac{p}{Q}

To confirm that this is the correct generating function, verify that it matches (Template:EquationNote):

q = - \frac{\partial F_{3}}{\partial p} = \frac{- 1}{Q}

References

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+'''Generating functions''' which arise in [[Hamiltonian mechanics]] are quite different from [[generating functions]] in mathematics.  In physics, a generating function acts as a bridge between two sets of canonical variables when performing a [[canonical transformation]].
+==Details==
+There are four basic generating functions, summarized by the following table:
+{| border="1" cellpadding="5" cellspacing="0"
+! style="background:#ffdead;" | Generating Function
+! style="background:#ffdead;" | Its Derivatives
+|-
+|<math>F= F_1(q, Q, t) \,\!</math>
+|<math>p = ~~\frac{\partial F_1}{\partial q} \,\!</math> and <math>P = - \frac{\partial F_1}{\partial Q} \,\!</math>
+|-
+|<math>F= F_2(q, P, t) - QP \,\!</math>
+|<math>p = ~~\frac{\partial F_2}{\partial q} \,\!</math> and <math>Q = ~~\frac{\partial F_2}{\partial P} \,\!</math>
+|-
+|<math>F= F_3(p, Q, t) + qp \,\!</math>
+|<math>q = - \frac{\partial F_3}{\partial p} \,\!</math> and <math> P = - \frac{\partial F_3}{\partial Q} \,\!</math>
+|-
+|<math>F= F_4(p, P, t) + qp - QP \,\!</math>
+|<math>q = - \frac{\partial F_4}{\partial p} \,\!</math> and <math> Q = ~~\frac{\partial F_4}{\partial P} \,\!</math>
+|}
+==Example==
+Sometimes a given Hamiltonian can be turned into one that looks like the [[harmonic oscillator]] Hamiltonian, which is
+:<math>H = aP^2 + bQ^2.</math>
+For example, with the Hamiltonian
+:<math>H = \frac{1}{2q^2} + \frac{p^2 q^4}{2},</math>
+where ''p'' is the generalized momentum and ''q'' is the generalized coordinate, a good canonical transformation to choose would be
+{{NumBlk|:|<math>P = pq^2 \text{ and }Q = \frac{-1}{q}. \,</math>|{{EquationRef|1}}}}
+This turns the Hamiltonian into
+:<math>H = \frac{Q^2}{2} + \frac{P^2}{2},</math>
+which is in the form of the harmonic oscillator Hamiltonian.
+The generating function ''F'' for this transformation is of the third kind,
+:<math>F = F_3(p,Q).</math>
+To find ''F'' explicitly, use the equation for its derivative from the table above,
+:<math>P = - \frac{\partial F_3}{\partial Q},</math>
+and substitute the expression for ''P'' from equation ({{EquationNote|1}}), expressed in terms of ''p'' and ''Q'':
+: <math>\frac{p}{Q^2} = - \frac{\partial F_3}{\partial Q}</math>
+Integrating this with respect to ''Q'' results in an equation for the generating function of the transformation given by equation ({{EquationNote|1}}):
+::{|cellpadding="2" style="border:2px solid #ccccff"
+|<math>F_3(p,Q) = \frac{p}{Q}</math>
+|}
+To confirm that this is the correct generating function, verify that it matches ({{EquationNote|1}}):
+: <math>q = - \frac{\partial F_3}{\partial p} = \frac{-1}{Q}</math>
+==See also==
+*[[Hamilton-Jacobi equation]]
+*[[Poisson bracket]]
+==References==
+*{{cite book | author=Goldstein, Herbert | title=Classical Mechanics | publisher=Addison Wesley | year=2002 | isbn=978-0-201-65702-9}}
+[[Category:Classical mechanics]]
+[[Category:Hamiltonian mechanics]]
+{{classicalmechanics-stub}}

Schur orthogonality relations: Difference between revisions

Revision as of 09:27, 8 November 2013

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Schur orthogonality relations: Difference between revisions

Revision as of 09:27, 8 November 2013

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Example

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References

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