Title :
Sufficient conditions for existence of a fixed point in stochastic reward net-based iterative models
Author :
Mainkar, Varsha ; Trivedi, Kishor S.
Author_Institution :
AT&T Bell Labs., Holmdel, NJ, USA
fDate :
9/1/1996 12:00:00 AM
Abstract :
Stochastic Petri net models of large systems that are solved by generating the underlying Markov chain pose the problem of largeness of the state-space of the Markov chain. Hierarchical and iterative models of systems have been used extensively to solve this problem. A problem with models which use fixed-point iteration is the theoretical proof of the existence, uniqueness and convergence of the fixed-point equations, which still remains an “art”. In this paper, we establish conditions, in terms of the net structure and the characteristics of the iterated variables, under which existence of a solution is guaranteed when fixed-point iteration is used in stochastic Petri nets. We use these conditions to establish the existence of a fixed point for a model of a priority scheduling system, at which tasks may arrive according to a Poisson process or due to spawning or conditional branching of other tasks in the system
Keywords :
Markov processes; Petri nets; hierarchical systems; iterative methods; large-scale systems; queueing theory; scheduling; state-space methods; stochastic processes; stochastic systems; Markov chain; Poisson process; conditional branching; convergence proof; existence proof; fixed-point equations; fixed-point iteration; hierarchical models; iterated variables; iterative models; large systems; net structure; priority scheduling system; spawning; state-space size; stochastic Petri nets; stochastic reward net-based iterative models; sufficient conditions; task arrival; uniqueness proof; Equations; Iterative methods; Laboratories; Petri nets; Power system modeling; State-space methods; Stochastic processes; Stochastic systems; Sufficient conditions; Workstations;
Journal_Title :
Software Engineering, IEEE Transactions on
