Difference between revisions of "Lamé equation"

A linear ordinary second-order differential equation in the complex domain

$$ \tag{1 } \frac{d ^ {2} w }{d z ^ {2} } = \ \left [ A + B {\mathcal p} ( z) \right ] w , $$

where $ {\mathcal p} ( z) $ is the Weierstrass $ {\mathcal p} $- function and $ A $ and $ B $ are constants. This equation was first studied by G. Lamé [1]; it arises in the separation of variables for the Laplace equation in elliptic coordinates. Equation (1) is also called the Weierstrass form of the Lamé equation. By a change of the independent variable in (1) one obtains Jacobi's form of the Lamé equation:

$$ \frac{d ^ {2} w }{d u ^ {2} } = \ \left [ C + D \mathop{\rm sn} ^ {2} u \right ] w . $$

There are also numerous algebraic forms of the Lamé equation, transition to which is carried out by various transformations of the independent variable in (1), for example:

$$ \tag{2 } \frac{d ^ {2} w }{d \xi ^ {2} } + \frac{1}{2} \left ( \frac{1}{\xi - e _ {1} } + \frac{1}{\xi - e _ {2} } + \frac{1}{\xi - e _ {3} } \right ) \frac{dw}{d \xi } = $$

$$ = \ \frac{A + B \xi }{4 ( \xi - e _ {1} ) ( \xi - e _ {2} ) ( \xi - e _ {3} ) } w . $$

For practical applications the Jacobi form is the most suitable.

Especially important is the case when in (1) (or (2)) $ B = n ( n + 1 ) $, where $ n $ is a natural number. In this case the solutions of (1) are meromorphic in the whole plane and their properties have been thoroughly studied. Among the solutions of (2) with $ B = n ( n + 1 ) $ the Lamé functions are of paramount importance (cf. Lamé function).

References