This is maybe more an open problem than a question, since I have seriously thought about it and asked several people working on algebraic surfaces with no success. I hope somebody here can suggest an approach different from the standard arguments in surface theory. BACKGROUND: let $X$ be a smooth minimal complex projective surface of general type. An *irrational pencil* is a morphism with connected fibers $f\colon S\to B$, with $B$ a smooth curve of genus $b>0$. For $b>1$, $X$ has at most finitely many pencils of genus $b$, having such a pencil is a topological property and it is possible to bound explicitly the genus of a general fiber of $f$ in terms of $K^2_X$ (Arakelov' theorem). For $b=1$, namely for *elliptic pencils*, things are very different in general: a surface can have infinitely many such pencils, the genus of the general fibers of these pencils can be unbounded, and it is possible that a surface with an elliptic pencil deforms to a surface without elliptic pencils. However, if $h^1({\mathcal O}_X)=1$, then the Albanese map $a\colon X\to Alb(X)$ is an elliptic pencil, and for fixed $K^2$ the genus of a general fiber of $a$ is bounded, since the moduli space of surfaces with fixed $K^2$ is quasiprojective. QUESTION: can one give for the genus of the general fiber of the Albanese pencil of a minimal surface of general type $X$ in terms of $K^2_X$? Such a bound would be very interesting in the fine classification of surfaces of general type.