Abstract
The paper explores properties of the {\L}ukasiewicz {\mu}-calculus, or {\L}{\mu} for short, an extension of {\L}ukasiewicz logic with scalar multiplication and least and greatest fixed-point operators (for monotone formulas). We observe that {\L}{\mu} terms, with $n$ variables, define monotone piecewise linear functions from $[0, 1]n$ to $[0, 1]$. Two effective procedures for calculating the output of {\L}{\mu} terms on rational inputs are presented. We then consider the {\L}ukasiewicz modal {\mu}-calculus, which is obtained by adding box and diamond modalities to {\L}{\mu}. Alternatively, it can be viewed as a generalization of Kozen's modal {\mu}-calculus adapted to probabilistic nondeterministic transition systems (PNTS's). We show how properties expressible in the well-known logic PCTL can be encoded as {\L}ukasiewicz modal {\mu}-calculus formulas. We also show that the algorithms for computing values of {\L}ukasiewicz {\mu}-calculus terms provide automatic (albeit impractical) methods for verifying {\L}ukasiewicz modal {\mu}-calculus properties of finite rational PNTS's.
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