A constructive fixed-point theorem and the feedback semantics of timed systems

Deterministic timed systems can be modeled as fixed point problems (B. Roscoe and G. Reed, 1988), (R. K. Yates, 1993), (E. A. Lee, 1999). In particular, any connected network of timed systems can be modeled as a single system with feedback, and the system behavior is the fixed point of the corresponding system equation, when it exists. For delta-causal systems, we can use the Cantor metric to measure the distance between signals and the Banach fixed-point theorem to prove the existence and uniqueness of a system behavior. Moreover, the Banach fixed-point theorem is constructive: it provides a method to construct the unique fixed point through iteration. In this paper, we extend this result to systems modeled with the superdense model of time (O. Maler et al., 1992), (Z. Manna and A. Pnueli, 1993) used in hybrid systems. We call the systems we consider eventually delta-causal, a strict generalization of delta-causal in which multiple events may be generated on a signal in zero time. With this model of time, we can use a generalized ultrametric (Generalized ultrametric spaces, I, 1996) instead of a metric to model the distance between signals. The existence and uniqueness of behaviors for such systems comes from the fixed-point theorem of (S. Priess-Crampe and P. Ribenboim, 1993), but this theorem gives no constructive method to compute the fixed point This leads us to define petrics, a generalization of metrics, which we use to generalize the Banach fixed-point theorem to provide a constructive fixed-point theorem. This new fixed-point theorem allows us to construct the unique behavior of eventually delta-causal systems

[1]  A. W. Roscoe,et al.  Metric Spaces as Models for Real-Time Concurrency , 1987, MFPS.

[2]  J. Quadrat,et al.  Algebraic tools for the performance evaluation of discrete event systems , 1989, Proc. IEEE.

[3]  Zohar Manna,et al.  From Timed to Hybrid Systems , 1991, REX Workshop.

[4]  Zohar Manna,et al.  Verifying Hybrid Systems , 1992, Hybrid Systems.

[5]  S. Priess-Crampe,et al.  Fixed points, combs and generalized power series , 1993 .

[6]  R. K. Yates,et al.  Networks of Real-Time Processes , 1993, CONCUR.

[7]  Paul Gastin,et al.  Selected papers of the workshop on Topology and completion in semantics , 1995 .

[8]  S. G. Matthews,et al.  An Extensional Treatment of Lazy Data Flow Deadlock , 1995, Theor. Comput. Sci..

[9]  P. Ribenboim,et al.  Generalized ultrametric spaces I , 1996 .

[10]  P. Ribenboim,et al.  Generalized ultrametric spaces II , 1996 .

[11]  Edward A. Lee,et al.  A framework for comparing models of computation , 1998, IEEE Trans. Comput. Aided Des. Integr. Circuits Syst..

[12]  Edward A. Lee Modeling concurrent real-time processes using discrete events , 1999, Ann. Softw. Eng..

[13]  Pieter J. Mosterman,et al.  An Overview of Hybrid Simulation Phenomena and Their Support by Simulation Packages , 1999, HSCC.

[14]  Holger Naundorf,et al.  Strictly causal functions have a unique fixed point , 2000, Theor. Comput. Sci..

[15]  K. Evans,et al.  Totally Ordered Commutative Monoids , 2001 .

[16]  Edward A. Lee,et al.  Operational Semantics of Hybrid Systems , 2005, HSCC.