Let $\Omega$ be a bounded regular domain in $\Bbb R^n$. In this paper, we study the following problem: find $u\in\displaystyle\prod^m_{i=1}W_0^{1,p_i}(\Omega)$ such that:
$$ -\Delta_{p_i}u_i=\frac{\partial F}{\partial x_i}(x,u) +h_i(x)\text{ in }\Omega,\quad 1\le i\le m \tag"(S)" $$ where $\Delta_{p_i}u_i=\operatorname{div}(|\nabla u_i|^{p-2}\nabla u_i)$, $1 We associate to (S) the eigenvalue problem: $$ -\Delta_p v_i=\lambda \alpha_i|v_i|^{\alpha_i-2}v_i\prod_{j\ne i}|v_j|^{\alpha_j}\tag"(VP)" $$ where $\alpha=(\alpha_1,\ldots,\alpha_m)$ satisfies $\alpha_i>0$ and $\displaystyle\sum^m_{i=1}\frac{\alpha_i}{p_i}=1$. We obtain nonresonance results for (S). Roughly speaking if $$ \lim\sup\frac{F(x,s)}{|s|^{\alpha}}<\lambda_1 $$ where $\lambda_1$ is the first eigenvalue of (VP), we prove the existence of a solution of (S).
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