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%0 Thesis
%A Psychou, Georgia
%T Stochastic Approaches for Speeding-Up the Analysis of the Propagation of Hardware-Induced Errors and Characterization of System-Level Mitigation Schemes in Digital Communication Systems
%I Rheinisch-Westfälische Technische Hochschule Aachen
%V Dissertation
%C Aachen
%M RWTH-2017-10881
%P 1 Online-Ressource (xiv, 123 Seiten) : Illustrationen
%D 2017
%Z Veröffentlicht auf dem Publikationsserver der RWTH Aachen University 2018
%Z Dissertation, Rheinisch-Westfälische Technische Hochschule Aachen, 2017
%X Today's nano-scale technology nodes are bringing reliability concerns back to the center stage of digital system design because of issues, like process variability, noise effects, radiation particles, as well as increasing variability at run time. Alleviations of these effects can become potentially very costly and the benefits of technology scaling can be significantly reduced or even lost. In order to build more robust digital systems, initially, their behavior in the presence of hardware-induced bit errors must be analyzed. In many systems, certain types of errors can be tolerated. These cases can be revealed through such an analysis. Overhead can be avoided and remedy measures can be applied only when needed. Communication systems are an interesting domain for such explorations: First, they have high societal relevance due to their ubiquity. Second, they can potentially tolerate hardware-induced errors due to their built-in redundancy present to cope with channel noise. This work focuses on analyzing the impact of such errors on the behavior of communication systems. Typically, error propagation studies are performed through time-consuming fault injection campaigns. These approaches do not scale well with growing system sizes. Stochastic experiments allow a more time-efficient approach. On top, breaking down the system into subsystems and propagating error statistics through each of these subsystems further improves the speed-up and flexibility in the reliability evaluation of complex systems. As an initial step in this thesis, statistical moments are propagated through the signal flows of Linear-Time-Invariant (LTI) blocks. Such a scheme, although fast, can only be applied in the case that the signal lacks autocorrelation. However, autocorrelation can be introduced in the signal due to various reasons, like by signal processing blocks. In that case, other approaches are available to reduce the computational cost of the necessary (repetitive) experiments, like the Principal Component Analysis (PCA). Benefits of such a technique depend on several parameters and, therefore, a more broadly usable technique is required. To address this need, a framework is proposed that exploits the repetitive nature of fault injection experiments for speed-up in LTI blocks. Two cases are distinguished: One, in which all operators of the LTI block act in a linear time-invariant way, and one, in which non-linear operations due to finite wordlengths are present. To complement the subject matter, the broad range of hardware-based mitigation techniques at the higher system level are explored and characterized. In this way, the main properties of each mitigation category are identified and, therefore, suitable choices can be made according to the application needs.
%F PUB:(DE-HGF)11
%9 Dissertation / PhD Thesis
%R 10.18154/RWTH-2017-10881
%U https://publications.rwth-aachen.de/record/711539