On an integral representation of the solution of the Laplace equation with mixed boundary conditions (Q662457)

Let \(D=\{(r,\vartheta ):0 < r< 1,0< \vartheta < \pi \}\), where \((r,\vartheta)\) are polar coordinates. The author studies the boundary value problem for the Laplace equation in \(D\) with the mixed boundary conditions \(u(1, \vartheta)=f(\vartheta)\) for \(\vartheta \in [0, \pi]\), \((\frac1r \frac{\partial u} {\partial \vartheta} + \tan \vartheta_0 \frac{\partial u}{\partial r})=0\) for \(\vartheta =0\), \((\frac1r \frac{\partial u}{\partial \vartheta} - \tan \vartheta_1 \frac{\partial u}{\partial r})=0\) for \(\vartheta = \pi\). A solution of the problem is represented in the form of a contour integral. If \(\vartheta_0 + \vartheta_1 < 0\) then there exists a nontrivial solution of the homogeneous problem. Two solutions of the homogeneous problem are linearly dependent.