Real-reward testing for probabilistic processes

Yuxin Deng; Rob van Glabbeek; Matthew Hennessy; Carroll Morgan

doi:10.1016/j.tcs.2013.07.016

Real-reward testing for probabilistic processes

Yuxin Deng^*
, Rob van Glabbeek
, Matthew Hennessy
, Carroll Morgan

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

We introduce a notion of real-valued reward testing for probabilistic processes by extending the traditional nonnegative-reward testing with negative rewards. In this richer testing framework, the may- and must-preorders turn out to be inverses. We show that for convergent processes with finitely many states and transitions, but not in the presence of divergence, the real-reward must-testing preorder coincides with the nonnegative-reward must-testing preorder. To prove this coincidence we characterise the usual resolution-based testing in terms of the weak transitions of processes, without having to involve policies, adversaries, schedulers, resolutions or similar structures that are external to the process under investigation. This requires establishing the continuity of our function for calculating testing outcomes.

Original language	English
Pages (from-to)	16-36
Number of pages	21
Journal	Theoretical Computer Science
Volume	538
Issue number	C
DOIs	https://doi.org/10.1016/j.tcs.2013.07.016
State	Published - 2014
Externally published	Yes

Keywords

Failure simulations
Probabilistic processes
Reward testing

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10.1016/j.tcs.2013.07.016

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title = "Real-reward testing for probabilistic processes",

abstract = "We introduce a notion of real-valued reward testing for probabilistic processes by extending the traditional nonnegative-reward testing with negative rewards. In this richer testing framework, the may- and must-preorders turn out to be inverses. We show that for convergent processes with finitely many states and transitions, but not in the presence of divergence, the real-reward must-testing preorder coincides with the nonnegative-reward must-testing preorder. To prove this coincidence we characterise the usual resolution-based testing in terms of the weak transitions of processes, without having to involve policies, adversaries, schedulers, resolutions or similar structures that are external to the process under investigation. This requires establishing the continuity of our function for calculating testing outcomes.",

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AU - Deng, Yuxin

AU - van Glabbeek, Rob

AU - Hennessy, Matthew

AU - Morgan, Carroll

PY - 2014

Y1 - 2014

N2 - We introduce a notion of real-valued reward testing for probabilistic processes by extending the traditional nonnegative-reward testing with negative rewards. In this richer testing framework, the may- and must-preorders turn out to be inverses. We show that for convergent processes with finitely many states and transitions, but not in the presence of divergence, the real-reward must-testing preorder coincides with the nonnegative-reward must-testing preorder. To prove this coincidence we characterise the usual resolution-based testing in terms of the weak transitions of processes, without having to involve policies, adversaries, schedulers, resolutions or similar structures that are external to the process under investigation. This requires establishing the continuity of our function for calculating testing outcomes.

AB - We introduce a notion of real-valued reward testing for probabilistic processes by extending the traditional nonnegative-reward testing with negative rewards. In this richer testing framework, the may- and must-preorders turn out to be inverses. We show that for convergent processes with finitely many states and transitions, but not in the presence of divergence, the real-reward must-testing preorder coincides with the nonnegative-reward must-testing preorder. To prove this coincidence we characterise the usual resolution-based testing in terms of the weak transitions of processes, without having to involve policies, adversaries, schedulers, resolutions or similar structures that are external to the process under investigation. This requires establishing the continuity of our function for calculating testing outcomes.

KW - Failure simulations

KW - Probabilistic processes

KW - Reward testing

UR - https://www.scopus.com/pages/publications/84926278878

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DO - 10.1016/j.tcs.2013.07.016

M3 - 文章

AN - SCOPUS:84926278878

SN - 0304-3975

VL - 538

SP - 16

EP - 36

JO - Theoretical Computer Science

JF - Theoretical Computer Science

IS - C

ER -

Real-reward testing for probabilistic processes

Abstract

Keywords

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