In mathematics, in the field of ordinary differential equations, a nontrivial solution to an ordinary differential equation
is called oscillating if it has an infinite number of roots; otherwise it is called non-oscillating. The differential equation is called oscillating if it has an oscillating solution. The number of roots carries also information on the spectrum of associated boundary value problems.
The differential equation
is oscillating as sin(x) is a solution.
Oscillation theory was initiated by Jacques Charles François Sturm in his investigations of SturmâÂÂLiouville problems from 1836. There he showed that the n'th eigenfunction of a SturmâÂÂLiouville problem has precisely n-1 roots. For the one-dimensional Schrödinger equation the question about oscillation/non-oscillation answers the question whether the eigenvalues accumulate at the bottom of the continuous spectrum.
In 1996 GesztesyâÂÂSimonâÂÂTeschl showed that the number of roots of the Wronski determinant of two eigenfunctions of a SturmâÂÂLiouville problem gives the number of eigenvalues between the corresponding eigenvalues. It was later on generalized by KrügerâÂÂTeschl to the case of two eigenfunctions of two different SturmâÂÂLiouville problems. The investigation of the number of roots of the Wronski determinant of two solutions is known as relative oscillation theory.
Classical results in oscillation theory are: