<matmzc%
[email protected]> wrote:
Hi all. �On any smooth surface one can use the metric to define
Christoffel symbols, define a covariant derivative, and a covariant
Laplacian which one can use to set up a wave equation. �For no
particular reason it occurred to me that one might get interesting
solutions of the wave equation on the hyperbolic plane or in hyperbolic 3-space. �A Google search didn't turn up anything. �Does anyone know of
any relevant literature? �I set up the wave equation for the unit disk
in the Poincare and Klein metrics, but in both cases I got a mess that
seems unsolvable (by humble me anyways). �Any thoughts on this? �Or
perhaps my idea that the problem is worth looking into was overly
optimistic?
Its standard.
The geometry is rotional invariant and in polar or spherical
coordinates
the scalar wave equation separates readily producing products of the 2d
or 3d the angular momentum operator times a solution of the radial
function that solves the radial equation
omega^2 psi - f(r)-1 d_r f(r) d_r psi �+ l^2/r^2 �psi = m^2 psi
where "l^2" is an eigenvalue of the angular momentum operator squared,
in �3D eg
L^2 = -csc tetha d_theta sin tetha �d_theta + m^2/(sin theta)^2
The exact form depends on dimension of course.
Google eg on scholar.google.com
https://books.google.de/books?hl=de&lr=&id=rIM8AAAAIAAJ&oi=fnd&pg=PA91&d q=metrics+on+the+hyperbolic+plane&ots=imtAYtaYru&sig=jZ93XruOzaGTEnIFxKK 3sI3Q5KU#v=onepage&q=metrics%20on%20the%20hyperbolic%20plane&f=false
--
Roland Franzius
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