Uncertainty propagation through software dependability models
dc.contributor.advisor | Trivedi, Kishor S | |
dc.contributor.advisor | Board, John A | |
dc.contributor.advisor | Chakrabarty, Krishnendu | |
dc.contributor.advisor | Lee, Benjamin C | |
dc.contributor.advisor | Gavin, Henri | |
dc.contributor.author | Mishra, Kesari | |
dc.date.accessioned | 2012-01-10T15:58:17Z | |
dc.date.issued | 2011 | |
dc.department | Electrical and Computer Engineering | |
dc.description.abstract | Systems in critical applications employ various hardware and software fault-tolerance techniques to ensure high dependability. Stochastic models are often used to analyze the dependability of these systems and assess the effectiveness of the fault-tolerance techniques employed. Measures like performance and performability of systems are also analyzed using stochastic models. These models take into account randomness in various events in the system (known as aleatory uncertainty) and are solved at fixed parameter values to obtain the measures of interest. However, in real life, the parameters of the stochastic models themselves are uncertain as they are derived from a finite (limited) number of observations or are simply based on expert opinions. Solving the stochastic models at fixed values of the model input parameters result in estimates of model output metrics which do not take into account the uncertainty in model input parameters (known as epistemic uncertainty). In this research work, we address the computation of uncertainty in output metrics of stochastic models due to epistemic uncertainty in model input parameters, with a focus on dependability and performance models of current computer and communication systems. We develop an approach for propagation of epistemic uncertainty in input parameters through stochastic dependability and performance models of varying complexity, to compute the uncertainty in the model output measures. The uncertainty propagation method can be applied to a wide range of stochastic model types with different model output measures. For simple analytic stochastic dependability models, we present a closed-form analytic method for epistemic uncertainty propagation, where we derive closed-form expressions for the expectation, distribution and variance of the model output metrics due to the epistemic uncertainty in the model input parameters. We analyze the results thus obtained and study their limiting behavior. For slightly more complex analytic stochastic models, where the closed-form expressions for the expectation, distribution and variance of the model output cannot be easily obtained, we present a numerical integration based method. For large and complex stochastic models, we develop a sampling based epistemic uncertainty propagation method which also considers dependencies in the input parameter values and is an improvement over previous sampling based uncertainty propagation approaches. The sampling based epistemic uncertainty propagation method explained in this dissertation acts as a wrapper to existing models and their solution types (hence the wide applicability) and provides more robust estimates of uncertainty in the model output metrics than previous sampling based methods. We demonstrate the applicability of the uncertainty propagation approach by applying it to analytic stochastic dependability and performance models of computer systems, ranging from simple non-state-space models with a few input parameters to large state-space models and even hierarchical models with more than fifty input parameters. We further apply the uncertainty propagation approach to stochastic models with not only analytic or analytic-numeric solutions but also those with simulative solutions. We also consider a wide range of model output metrics including reliability and availability of computer systems, response time of a web service, capacity oriented availability of a communication system, security (probability ofsuccessful attack) of a network routing session, expected number of jobs in a queueing system with breakdown and repair of servers and call handoff probability of a cellular wireless communication cell. | |
dc.identifier.uri | ||
dc.title | Uncertainty propagation through software dependability models | |
dc.type | Dissertation | |
pubs.organisational-group | Duke | |
pubs.organisational-group | Duke | |
pubs.organisational-group | Pratt School of Engineering | |
pubs.organisational-group | Duke | |
pubs.organisational-group | Pratt School of Engineering | |
pubs.organisational-group | Electrical and Computer Engineering | |
pubs.organisational-group | Duke | |
pubs.organisational-group | Trinity College of Arts & Sciences | |
pubs.organisational-group | Duke | |
pubs.organisational-group | Trinity College of Arts & Sciences | |
pubs.organisational-group | Computer Science | |
pubs.publication-status | Published |
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