This paper deals with study of the nonlinear singular elliptic equations
in a bounded domain
$\Omega\subset\mathbb{R}^N$,
$(N\geq2)$ with Lipschitz boundary
$\partial\Omega$, $$
Au=\frac{f}{u^{\gamma(\cdot)}}+\mu,
$$ Where
$A:=-\mathrm{div}\left(\widehat{a}(\cdot,Du)\right)$
is a Leray-Lions type operator which maps continuously
$W^{1,p(\cdot)}_0(\Omega)$ into
its dual
$W^{-1,p’(\cdot)}(\Omega)$, whose
simplest model is the $p(\cdot)$-laplacian type
operator ( i.e.
$\widehat{a}(\cdot,\xi)=|\xi|^{p(\cdot)-2}\xi$
), such taht $f$ is a nonnegative function belonging to the Lebesgue
space with variable exponents
$L^{m(\cdot)}(\Omega)$, with
$m(\cdot)$ being small ( or
$L^{1}(\Omega)$ ) and $\mu$ is a
nonnegative bounded Radon measure, while
$m:\overline{\Omega}\to
(1,+\infty)$,
$\gamma:\overline{\Omega}\to
(0,1)$ are continuous functions satisfying certain conditions depend on
$p(\cdot)$. We prove the existence, uniqueness and
regularity of nonnegative weak solutions or this class of problems with
$p(\cdot)$-growth conditions. More precisely, we will
discuss that the nonlinear singular term has some regularizing effects
on the solutions of our problem which depends on the summability of
$f$, $m(\cdot)$ and the value of
$\gamma(\cdot)$. The functional
framework involves Sobolev spaces with variable exponents as well as
Lebesgue spaces with variable exponents. Our results can be seen as a
generalization of some results given in the constant exponents case.